From cf0c74e107c5b56fd3f0b425e1e103f4bb47c1ff Mon Sep 17 00:00:00 2001
From: Christian Pointner <equinox@anytun.org>
Date: Sat, 5 Dec 2009 13:33:22 +0000
Subject: removed common stuff (moved to repo anytun-common)

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 ...nycast VOIP Proxy Resultat und Meilensteine.pdf |  Bin 24937 -> 0 bytes
 papers/Anycast VOIP Proxy Zeitplan.pdf             |  Bin 10546 -> 0 bytes
 papers/Dokumentation.odt                           |  Bin 28184 -> 0 bytes
 papers/Makefile                                    |   13 -
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 papers/acn/app_anycast_rtp_proxy.dia               |  Bin 3323 -> 0 bytes
 papers/acn/app_securing_anycast_services.dia       |  Bin 3398 -> 0 bytes
 papers/acn/app_tunnel_2_networks.dia               |  Bin 2907 -> 0 bytes
 papers/acn/app_unicast_vpn_concentrator.dia        |  Bin 3320 -> 0 bytes
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 ...intner-secure-anycast-tunneling-protocol-01.txt | 1456 --------------------
 ...intner-secure-anycast-tunneling-protocol-01.xml |  527 -------
 ...enger-secure-anycast-tunneling-protocol-02.html |  687 ---------
 ...senger-secure-anycast-tunneling-protocol-02.txt |  952 -------------
 ...senger-secure-anycast-tunneling-protocol-02.xml |  299 ----
 papers/linuxtage2008.odp                           |  Bin 102663 -> 0 bytes
 papers/realraum.odp                                |  Bin 102953 -> 0 bytes
 papers/titelseite_anycast_und_kryptographie.odt    |  Bin 8907 -> 0 bytes
 papers/vortrag                                     |   21 -
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 delete mode 100644 papers/Anycast VOIP Proxy Resultat und Meilensteine.pdf
 delete mode 100644 papers/Anycast VOIP Proxy Zeitplan.pdf
 delete mode 100644 papers/Dokumentation.odt
 delete mode 100644 papers/Makefile
 delete mode 100644 papers/acn/acn.ppt
 delete mode 100644 papers/acn/anycast-dns-lan.dia
 delete mode 100644 papers/acn/app_anycast_rtp_proxy.dia
 delete mode 100644 papers/acn/app_securing_anycast_services.dia
 delete mode 100644 papers/acn/app_tunnel_2_networks.dia
 delete mode 100644 papers/acn/app_unicast_vpn_concentrator.dia
 delete mode 100644 papers/acn/enc4-6ur.dia
 delete mode 100644 papers/acn/enc6-e.dia
 delete mode 100644 papers/acn/header-auth.dia
 delete mode 100644 papers/acn/header-enc.dia
 delete mode 100644 papers/acn/header.dia
 delete mode 100644 papers/acn/kd-auth.dia
 delete mode 100644 papers/acn/kd-enc.dia
 delete mode 100644 papers/acn/kx-ipsec.dia
 delete mode 100644 papers/acn/kx-ovpn.dia
 delete mode 100644 papers/acn/kx-satp.dia
 delete mode 100644 papers/anycast-voip-diagramm.pdf
 delete mode 100644 papers/anycast_und_kryptographie.odt
 delete mode 100644 papers/anycast_und_kryptographie.pdf
 delete mode 100644 papers/draft-gsenger-pointner-secure-anycast-tunneling-protocol-01.txt
 delete mode 100644 papers/draft-gsenger-pointner-secure-anycast-tunneling-protocol-01.xml
 delete mode 100644 papers/draft-gsenger-secure-anycast-tunneling-protocol-02.html
 delete mode 100644 papers/draft-gsenger-secure-anycast-tunneling-protocol-02.txt
 delete mode 100644 papers/draft-gsenger-secure-anycast-tunneling-protocol-02.xml
 delete mode 100644 papers/linuxtage2008.odp
 delete mode 100644 papers/realraum.odp
 delete mode 100644 papers/titelseite_anycast_und_kryptographie.odt
 delete mode 100644 papers/vortrag

(limited to 'papers')

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-		 draft-gsenger-secure-anycast-tunneling-protocol-02.txt
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-all: doc
-doc: $(PAPERS)
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-
-Network Working Group                                         O. Gsenger
-Internet-Draft                                               C. Pointner
-Expires: October 3, 2009                                      April 2009
-
-
-                secure anycast tunneling protocol (SATP)
-      draft-gsenger-pointner-secure-anycast-tunneling-protocol-01
-
-Status of this Memo
-
-   By submitting this Internet-Draft, each author represents that any
-   applicable patent or other IPR claims of which he or she is aware
-   have been or will be disclosed, and any of which he or she becomes
-   aware will be disclosed, in accordance with Section 6 of BCP 79.
-
-   Internet-Drafts are working documents of the Internet Engineering
-   Task Force (IETF), its areas, and its working groups.  Note that
-   other groups may also distribute working documents as Internet-
-   Drafts.
-
-   Internet-Drafts are draft documents valid for a maximum of six months
-   and may be updated, replaced, or obsoleted by other documents at any
-   time.  It is inappropriate to use Internet-Drafts as reference
-   material or to cite them other than as "work in progress."
-
-   The list of current Internet-Drafts can be accessed at
-   http://www.ietf.org/ietf/1id-abstracts.txt.
-
-   The list of Internet-Draft Shadow Directories can be accessed at
-   http://www.ietf.org/shadow.html.
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-   This Internet-Draft will expire on October 3, 2009.
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-Gsenger & Pointner       Expires October 3, 2009                [Page 1]
-
-Internet-Draft  secure anycast tunneling protocol (SATP)      April 2009
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-
-Abstract
-
-   The secure anycast tunneling protocol (SATP) defines a protocol used
-   for communication between any combination of unicast and anycast
-   tunnel endpoints.  It allows tunneling of every ETHER TYPE protocol
-   (ethernet, ip ...).  SATP directly includes cryptography and message
-   authentication based on the methods used by the Secure Real-time
-   Transport Protocol(SRTP) [RFC3711].  It can be used as an encrypted
-   alternative to IP Encapsulation within IP [RFC2003] and Generic
-   Routing Encapsulation (GRE) [RFC2784].  Both anycast receivers and
-   senders are supported.
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-Gsenger & Pointner       Expires October 3, 2009                [Page 2]
-
-Internet-Draft  secure anycast tunneling protocol (SATP)      April 2009
-
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-Table of Contents
-
-   1.  Introduction . . . . . . . . . . . . . . . . . . . . . . . . .  4
-     1.1.  Notational Conventions . . . . . . . . . . . . . . . . . .  4
-   2.  Motivation and usage scenarios . . . . . . . . . . . . . . . .  5
-     2.1.  Usage scenarions . . . . . . . . . . . . . . . . . . . . .  5
-       2.1.1.  Tunneling from unicast hosts over anycast routers
-               to other unicast hosts . . . . . . . . . . . . . . . .  5
-       2.1.2.  Tunneling from unicast hosts to anycast networks . . .  6
-       2.1.3.  Redundant tunnel connection of 2 networks  . . . . . .  6
-     2.2.  Encapsulation  . . . . . . . . . . . . . . . . . . . . . .  7
-   3.  Using SATP on top of IP  . . . . . . . . . . . . . . . . . . .  9
-     3.1.  Fragmentation  . . . . . . . . . . . . . . . . . . . . . .  9
-     3.2.  ICMP messages  . . . . . . . . . . . . . . . . . . . . . .  9
-   4.  Protocol specification . . . . . . . . . . . . . . . . . . . . 10
-     4.1.  Header format  . . . . . . . . . . . . . . . . . . . . . . 10
-     4.2.  sequence number  . . . . . . . . . . . . . . . . . . . . . 10
-     4.3.  sender ID  . . . . . . . . . . . . . . . . . . . . . . . . 10
-     4.4.  MUX  . . . . . . . . . . . . . . . . . . . . . . . . . . . 10
-     4.5.  payload type . . . . . . . . . . . . . . . . . . . . . . . 10
-     4.6.  payload  . . . . . . . . . . . . . . . . . . . . . . . . . 11
-     4.7.  padding (OPTIONAL) . . . . . . . . . . . . . . . . . . . . 11
-     4.8.  padding count (OPTIONAL) . . . . . . . . . . . . . . . . . 11
-     4.9.  authentication tag (RECOMMENDED) . . . . . . . . . . . . . 11
-   5.  Cryptography . . . . . . . . . . . . . . . . . . . . . . . . . 12
-     5.1.  Basic Concepts . . . . . . . . . . . . . . . . . . . . . . 12
-       5.1.1.  Cryptographic Contexts . . . . . . . . . . . . . . . . 12
-       5.1.2.  SATP Packet Processing . . . . . . . . . . . . . . . . 13
-       5.1.3.  Key derivation . . . . . . . . . . . . . . . . . . . . 15
-     5.2.  Predefined Transforms  . . . . . . . . . . . . . . . . . . 16
-       5.2.1.  Encryption . . . . . . . . . . . . . . . . . . . . . . 16
-       5.2.2.  Authentication and Integrity . . . . . . . . . . . . . 18
-       5.2.3.  Key Derivation Pseudo Random Functions . . . . . . . . 18
-     5.3.  Adding SATP Transforms . . . . . . . . . . . . . . . . . . 19
-   6.  Key Managment and Anycast Synchronization Considerations . . . 20
-   7.  Security Considerations  . . . . . . . . . . . . . . . . . . . 21
-     7.1.  Replay protection  . . . . . . . . . . . . . . . . . . . . 21
-   8.  IANA Considerations  . . . . . . . . . . . . . . . . . . . . . 22
-   9.  References . . . . . . . . . . . . . . . . . . . . . . . . . . 23
-     9.1.  Normative References . . . . . . . . . . . . . . . . . . . 23
-     9.2.  Informational References . . . . . . . . . . . . . . . . . 23
-   Authors' Addresses . . . . . . . . . . . . . . . . . . . . . . . . 25
-   Intellectual Property and Copyright Statements . . . . . . . . . . 26
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-1.  Introduction
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-   SATP is a mixture of a generic encapsulation protocol like GRE
-   [RFC2784] and a secure tunneling protocol as IPsec [RFC2401] in
-   tunnel mode.  It can be used to build redundant virtual private
-   network (VPN) connections.  It supports peer-to-peer tunnels, where
-   tunnel endpoints can be any combination of unicast, multicast or
-   anycast hosts, so it defines a Host Anycast Service [RFC1546].
-   Encryption is done per packet, so the protocol is robust against
-   packet loss and routing changes.  To reduce header overhead,
-   encryption techniques similar to SRTP [RFC3711] are being used.
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-1.1.  Notational Conventions
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-   The keywords "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT",
-   "SHOULD", "SHOULD NOT", "RECOMMENDED", "MAY", and "OPTIONAL" in this
-   document are to be interpreted as described in RFC2119 [RFC2119].
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-2.  Motivation and usage scenarios
-
-   This section gives an overview of possible usage scenarios.  Please
-   note that the protocols used in the figures are only examples and
-   that SATP itself does not care about either transport protocols or
-   encapsulated protocols.  Routing is not done by SATP and each
-   implemetation MAY choose it's own way of doing this task (e.g. using
-   functions provided by the operating system).  SATP is used only to
-   encapsulate and encrypt data.
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-2.1.  Usage scenarions
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-2.1.1.  Tunneling from unicast hosts over anycast routers to other
-        unicast hosts
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-   An example of SATP used to tunnel in a unicast client - anycast
-   server model
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-                       --------- router -----------
-                      /                            \
-       unicast ------+---------- router ------------+------ unicast
-       host           \                            /        host
-                       --------- router -----------
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-     unicast  | encrypted     |  anycast  | encrypted     |  unicast
-     tunnel   | communication |  tunnel   | communication |  tunnel
-     endpoint | using SATP    |  endpoint | using SATP    |  endpoint
-
-                                 Figure 1
-
-   In this scenario the payload is encapsuleted into a SATP packet by a
-   unicast host and gets transmitted to one of the anycast routers.
-   After transmisson the packet gets decapsulated by the router.  This
-   router makes a routing descision based on the underlying protocol and
-   transmits a new SATP package to one or more unicast hosts depending
-   on this decision.
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-2.1.2.  Tunneling from unicast hosts to anycast networks
-
-   An example of SATP used to encrypt data between a unicast host and
-   anycast networks
-
-                          -------Router -+---- DNS Server
-                         /                \
-                        /                  --- 6to4 Router
-                       /
-       unicast -------+----------Router --+--- DNS Server
-       host            \                   \
-                        \                   --- 6to4 Router
-                         \
-                          -------Router -+---- DNS Server
-                                          \
-                                           --- 6to4 Router
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-     unicast  | encrypted     |  anycast  | plaintext
-     tunnel   | communication |  tunnel   | anycast
-     endpoint | using SATP    |  endpoint | services
-
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-                                 Figure 2
-
-   When the unicast hosts wants to transmit data to one of the anycast
-   DNS servers, it encapsulates the data and sends a SATP packet to the
-   anycast address of the routers.  The packet arrives at one of the
-   routers, gets decapsulated and is then forwarded to the DNS server.
-   This method can be used to tunnel between clients and networks
-   providing anycast services.  It can also be used the other way to
-   virtually locate a unicast service within anycasted networks.
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-2.1.3.  Redundant tunnel connection of 2 networks
-
-   An example of SATP used to connect 2 networks
-
-                 Router -----------   ---------------Router
-               /                   \ /                     \
-       Network - Router ------------x                       Network
-          A    \                   / \                     /   B
-                 Router -----------   ---------------Router
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-               | packets       |  packets  |  packets      |
-    plaintext  | get           |  take a   |  get          | plaintext
-    packets    | de/encrypted  |  random   |  de/encrypted | packets
-               |de/encapsulated|   path    |de/encapsulated|
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-                                 Figure 3
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-   Network A has multiple routers which act as gateway/tunnel endpoints
-   to another network B. This way a redundant encrypted tunnel
-   connection between the two networks is built up.  All tunnel
-   endpoints of network A share the same anycast address and all tunnel
-   endpoints of network B share another anycast address.  When a packet
-   from network A is transmitted to network B, it first arrives on one
-   of network A's border routers.  Which router is used is determined by
-   network A's internal routing.  This router encapsulates the package
-   and sends it to the anycast address of network B's routers.  After
-   arrival the SATP packet gets decapsulated and routed to its
-   destination within network B.
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-2.2.  Encapsulation
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-   SATP does not depend on the lower layer protocol.  This section only
-   gives an example of how packets could look like.
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-   Examples of SATP used with different lower layer and payload
-   protocols
-
-       +------+-----+-------------------------------+
-       |      |     |      +----------------+-----+ |
-       | IPv6 | UDP | SATP | Ethernet 802.3 | ... | |
-       |      |     |      +----------------+-----+ |
-       +------+-----+-------------------------------+
-
-   Tunneling of Ethernet over UDP/IPv6
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-       +------+-----+---------------------------+
-       |      |     |      +------+-----+-----+ |
-       | IPv4 | UDP | SATP | IPv6 | UDP | RTP | |
-       |      |     |      +------+-----+-----+ |
-       +------+-----+---------------------------+
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-   Tunneling of IPv6 over UDP/IPv4 with RTP payload
-
-       +------+-------------------------------+
-       |      |      +----------------+-----+ |
-       | IPv6 | SATP | Ethernet 802.3 | ... | |
-       |      |      +----------------+-----+ |
-       +------+-------------------------------+
-
-   Tunneling of Ethernet over IPv6
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-       +------+---------------------------+
-       |      |      +------+-----+-----+ |
-       | IPv4 | SATP | IPv6 | UDP | RTP | |
-       |      |      +------+-----+-----+ |
-       +------+---------------------------+
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-   Tunneling of IPv6 over IPv4 with RTP payload
-
-                                 Figure 4
-
-
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-
-3.  Using SATP on top of IP
-
-3.1.  Fragmentation
-
-   The only way of fully supporting fragmentation would be to
-   synchronise fragments between all anycast servers.  This is
-   considered to be too much overhead, so there are two non-perfect
-   solutions for these problems.  Either fragmentation HAS TO be
-   disabled or if not all fragments arrive at the same server the IP
-   datagramm HAS TO be discarded.  As routing changes are not expected
-   to occur very frequently, the encapsulated protocol can do a
-   retransmission and all fragments will arrive at the new server.
-
-   If the payload type is IP and the IP headers' Don't Fragment (DF) bit
-   is set, then the DF bit of the outer IP header HAS TO be set as well.
-
-3.2.  ICMP messages
-
-   ICMP messages MUST be relayed according to rfc2003 section 4
-   [RFC2003].  This is needed for path MTU detection.
-
-
-
-
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-4.  Protocol specification
-
-4.1.  Header format
-
-   Protocol Format
-
-      0                   1                   2                   3
-      0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
-     +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
-     |                         sequence number                       | |
-     +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ |
-     |           sender ID           |              MUX              | |
-   +#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+ |
-   | |         payload type          |                               | |
-   | +-------------------------------+                               | |
-   | |              ....        payload        ...                   | |
-   | |                               +-------------------------------+ |
-   | |                               | padding (OPT) | pad count(OPT)| |
-   +#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+-+
-   | :                 authentication tag (RECOMMENDED)              : |
-   | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ |
-   |                                                                   |
-   +- Encrypted Portion                       Authenticated Portion ---+
-
-                                 Figure 5
-
-4.2.  sequence number
-
-   The sequence number is a 32 bit unsigned integer in network byte
-   order.  The starting point is signaled by the key exchange mechanism
-   and then value is then increased by 1 for every packet sent.  After
-   the maximum value it starts over from 0.
-
-4.3.  sender ID
-
-   The sender ID is a 16 bit unsigned integer.  It HAS TO be unique for
-   every sender sharing the same anycast address.
-
-4.4.  MUX
-
-   The MUX (multiplex) field is a 16 bit unsigned integer.  It is used
-   to distinguish multiple tunnel connections.
-
-4.5.  payload type
-
-   The payload type field defines the payload protocol.  ETHER TYPE
-   protocol numbers are used.  See IANA assigned ethernet numbers [1] .
-   The values 0000-05DC are reserverd and MUST NOT be used.
-
-
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-   Some examples for protocol numbers
-
-   HEX
-   0000 Reserved
-   .... Reserved
-   05DC Reserved
-   0800 Internet IP (IPv4)
-   6558 transparent ethernet bridging
-   86DD IPv6
-
-                                 Figure 6
-
-4.6.  payload
-
-   A packet of type payload type (e.g. an IP packet).
-
-4.7.  padding (OPTIONAL)
-
-   Padding of max 255 octets.  None of the pre-defined encryption
-   transforms uses any padding; for these, the plaintext and encrypted
-   payload sizes match exactly.  Transforms which may be added in future
-   (see Section 5.3) MUST define wheter they need padding or not and if
-   they need it they MUST define a proper padding format.  If the
-   padding count field is present, the padding count field MUST be set
-   to the padding length.
-
-4.8.  padding count (OPTIONAL)
-
-   The number of octets of the padding field.  This field is optional.
-   Its presence is signaled by the key management and not by this
-   protocol.  If this field isn't present, the padding field MUST NOT be
-   present as well.
-
-4.9.  authentication tag (RECOMMENDED)
-
-   The authentication tag is RECOMMENDED and of configurable length.  It
-   contains a cryptographic checksum of the sender ID, sequence number
-   and the encrypted portion.  On transmitter side encryption HAS TO be
-   done before calculating the authentication tag.  A receiver HAS TO
-   calculate the authentication tag before decrypting the encrypted
-   portion.
-
-
-
-
-
-
-
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-5.  Cryptography
-
-   As mentioned earlier the cryptography of SATP is based on SRTP
-   [RFC3711].  For that reason we recommend to read this document as
-   well (especially chapter 7 Rationale).  However some modifications
-   were made in order to fit the changed conditions of SATP.  The
-   following section describes the whole cryptography of SATP.
-
-5.1.  Basic Concepts
-
-   In order to cope with anycast and packet loss it is important to be
-   able to process one packet on its own without the need for packets
-   from the past as an additional information source.  Therefore SATP as
-   well as SRTP [RFC3711] defines a so called cryptographic context.
-   This context consits of all information which is needed to process a
-   single SATP packet and is divided into packet specific parameters and
-   global parameters.  The packet specific parameters can be found in
-   the protocol header and global parameters have to be generated by the
-   key exchange mechanism external to SATP (see Section 6).  For anycast
-   sender the global parameters have to be synchronized between all
-   hosts which share the same anycast address.  The packet specific
-   parameters MUST NOT be synchronized.
-   SATP uses two types of keys: master keys and session keys.  A session
-   key is meant to be used for a cryptographic transform (encrytion or
-   message authentication) for one packet.  The master keys are used to
-   derive packet-specific session keys in a cryptographical secure way.
-
-5.1.1.  Cryptographic Contexts
-
-5.1.1.1.  Global Parameters
-
-   As mentioned above global parameters HAVE TO either be provided by
-   the key exchange mechanism or configured manually.
-
-   o  a master key(s) which MUST be random and kept secret.
-
-   o  a master salt which MUST be random and MAY be public (RECOMMENDED
-      to be kept secret as well).
-
-   o  a role specifier used by the key derivation to determine which
-      session keys to generate for outbound or inbound traffic.
-
-   o  identifier for the key derivation pseudo random function.
-
-   o  identifier for the encryption algorithm (i.e. cipher and its mode
-      of operation).
-
-
-
-
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-   o  if used an identifier for the authentication algorithm.
-
-   o  transform specific parameters such as key lengths, see
-      Section 5.2.
-
-   o  if used the length of the authentication tag which should be
-      truncated to the packet.
-
-   o  an indicator which specifies if padding is needed or not (presence
-      of padding count field).
-
-   o  a replay list for each sender (see Section 5.1.1.3), maintained by
-      the receiver which contains the sequence numbers of received and
-      authenticated packets, this lists may be implemented as a sliding
-      window.
-
-   o  a [ From , To ] value pair which specifies the lifetime of a
-      master key (including the range endpoints), expressed in terms of
-      a pair of 32-bit sequence numbers.
-
-5.1.1.2.  Packet-Specific Parameters
-
-   o  the sequence number
-
-   o  the sender id
-
-   o  the mux value
-
-5.1.1.3.  Mapping SATP packets to Cryptographic Contexts
-
-   A cryptographic contexts SHALL be uniquely identifed by the tuple
-   context identifier:
-
-   context id = [ source address , source port ]
-
-   In order to cope with anycast sender and replay protection there HAS
-   TO be more than one replay list per context.  Each replay list inside
-   a cryptographic context SHALL be uniquely identified by the sender
-   id.
-
-5.1.2.  SATP Packet Processing
-
-   Before any SATP packet can be processed a cryptographic context HAS
-   TO be initialized by the key management mechanism.  After that a SATP
-   sender SHALL do the following to create a SATP packet:
-
-   1.  Determine the next sequence number to use.
-
-
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-   2.  Determine the crypotgraphic context as described in
-       Section 5.1.1.3.
-
-   3.  Determine the master key and master salt for the packets sequence
-       number.
-
-   4.  Compute all session keys and session salts which are needed by
-       the encryption transform using the key derivation pseudo random
-       function.
-
-   5.  Encrypt the payload type field concatenated with the payload to
-       produce the encrypted portion of the packet using the encryption
-       algorithm defined by the cryptographic context.
-
-   6.  Fill in sender id, mux and sequence number fields.
-
-   7.  If needed compute the session authentication key using the key
-       derivation pseudo random function.
-
-   8.  Generate the authentication tag over the authenticated portion
-       using the authentication algorithm defined by the cryptographic
-       context and append it to the packet.
-
-   On receiver side the packet SHALL be processed as follows:
-
-   1.   Determine the crypotgraphic context as described in
-        Section 5.1.1.3.
-
-   2.   Determine the master key and master salt for the packets
-        sequence number.
-
-   3.   Check if the packet was replayed using the replay list for the
-        packets sender id.
-
-   4.   If needed compute the session authentication key using the key
-        derivation pseudo random function.
-
-   5.   Generate the authentication tag over the authenticated portion
-        using the authentication algorithm defined by the crpyptographic
-        context and compare it with the tag appended to the received
-        packet.  If it is equal remove the tag and move on.  If it is
-        not equal drop the packet.
-
-   6.   Store the sequence number in the replay list.
-
-   7.   Compute all session keys and session salts which are needed by
-        the encryption transform using the key derivation pseudo random
-        function.
-
-
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-   8.   Decrypt the encrypted portion using the encryption algorithm
-        defined by the cryptographic context.
-
-   9.   Check if the payload type is supported by this tunnel endpoint
-        and discard the packet in case it isn't supported.
-
-   10.  Remove all fields beside the payload itself from the packet.
-
-5.1.3.  Key derivation
-
-   Any encryption or message authentication transform which is used
-   (predefined or newly introduced according to Section 5.3) MUST obtain
-   its secret values (keys and salts) using the SATP key derivation.
-   After the key exchange mechanism has signaled all needed parameters
-   (i.e. master key and salt) no additional communiction between sender
-   and receiver is needed until the next rekeying takes place.  To
-   achieve this the key derivation uses an pseudo random function seeded
-   by the master key, master salt, the packets sequence number and a
-   label (identifier for the key to compute).
-
-   SATP key derivation
-
-      packet sequence nummber ----+
-                                  |
-                                  V
-     +------------+ master +------------+
-     |            | key    |            |--> session encryption key
-     | ext. key   |------->| key        |
-     | management |        |            |--> session encryption salt
-     | mechanism  |------->| derivation |
-     |            | master |            |--> session authentication key
-     +------------+ salt   +------------+
-
-                                 Figure 7
-
-   SRTP [RFC3711] defines a pseudo random function as follows:
-   Let m and n be positive integers.  A pseudo-random function family is
-   a set of keyed functions {PRF_n(k,x)} such that for the (secret)
-   random key k, given m-bit x, PRF_n(k,x) is an n-bit string,
-   computationally indistinguishable from random n-bit strings.
-
-   For SATP key generation a pseudo random function with at least m =
-   128 MUST be used.  A predefined transform can be found in
-   Section 5.2.3.  The input x of the PRF SHOULD be calculated as
-   follows:
-
-   1.  Let key_id = label || sequence_number, with label defined as
-       below.
-
-
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-   2.  Let x = key_id XOR master_salt, where key_id and master_salt are
-       aligend so that their least significant bits agree (right-
-       alignment).
-
-   For each key derived by the key derivation there MUST exist a unique
-   label, a 32-bit constant.  In order to increase security SATP uses
-   different session keys for inbound and outbound traffic.  The role
-   specifier from the cryptographic context is used to determine which
-   session keys to use for inbound and outbound packets.  The labels can
-   be computed by calculateing the SHA1 hash over an increasing label-
-   index.  The label value are the 32 leftmost bits of this hash value.
-   We currently define 6 labels (label-index from 1 to 6) future
-   extensions may use labels with an index from 7 upwards.
-
-         +--------------------+-------+-------------+------------+
-         | key type           | role  | label-index |    label   |
-         +--------------------+-------+-------------+------------+
-         | encryption key     | left  |      1      | 0x356A192B |
-         |                    |       |             |            |
-         | encryption key     | right |      2      | 0xDA4B9237 |
-         |                    |       |             |            |
-         | encryption salt    | left  |      3      | 0x77DE68DA |
-         |                    |       |             |            |
-         | encryption salt    | right |      4      | 0x1B645389 |
-         |                    |       |             |            |
-         | authentication key | left  |      5      | 0xAC3478D6 |
-         |                    |       |             |            |
-         | authentication key | right |      6      | 0xC1DFD96E |
-         +--------------------+-------+-------------+------------+
-
-                           Key Derivation Labels
-
-   The role parameter specifies which label should be used for outbound
-   packets.  This means a endpoint with role left MUST use the labels
-   marked with left for outgoing packets and expects inbound packets to
-   be encrypted/authenticated using the labels marked with right.
-
-5.2.  Predefined Transforms
-
-   While SATP as well as SRTP allows the use of various encryption and
-   message authentication algorithms interoperable implementations MUST
-   support at least the following transforms.  To add additional
-   transforms see Section 5.3.
-
-5.2.1.  Encryption
-
-
-
-
-
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-5.2.1.1.  NULL Encryption
-
-   If confidendtiality of the SATP packet is not an issue the null
-   encryption transform can be used to increase performance.  This
-   transform just copies the plaintext input into the ciphertext output
-   wihtout any padding.  The identifier for that transfrom SHOULD be
-   NULL and it don't needs any transform specific parameters.  It also
-   doesn't need any key or salt values computed by the key derivation.
-
-5.2.1.2.  AES in Counter Mode
-
-   The following describes how to use AES in counter mode for SATP
-   encryption.  The identifier for that transform SHOULD be AES-CTR-
-   <key_length> or just AES-CTR in which case the key length defaults to
-   128 bits.  Beside the key length there are no additional transfrom
-   specific parameters.  This transform needs a key of length
-   <key_length> and a 112 bit salt.  These values can be generated using
-   the key derivation pseudo random function as follows:
-
-   session_key = PRF_<key_length>(master_key, x)
-   session_salt = PRF_112(master_key, x)
-   with PRF and x defined as in Section 5.1.3.
-
-   Basically AES in counter mode generates a pseudo random keystream
-   seeded by the session key, session salt as well as the sequence
-   number, sender id and mux value of the packet and encrypts a single
-   SATP packet using this stream.  The encryption process consits of the
-   generation of that keystream and then bitwise exclusive-oring it onto
-   the packets payload.  If the packet length doesn't fit a multiple of
-   128 bits the remaining bits (least significant) of the keystream are
-   simple ingored.  Therefore this transform does not need any padding.
-   Decryption of the packet can be achieved by generating the same
-   keystream and exclusive-oring it onto the encrypted portion.
-
-5.2.1.2.1.  Keystream Generation
-
-   In principle AES in counter mode consists of encrypting an
-   incrementing integer.  However the starting point of the integer
-   value has to be randomized to get a good pseudo random key stream.  A
-   keystream consits of several keystream segements with a size of 128
-   bits (AES blocksize).  Each segement can be computed by applying AES
-   with key k on the block CTR.  The whole keystream is a concatination
-   of all its successive segements.  Therefore a keystream looks as
-   follows:
-
-   AES(session_key, CTR) || AES(session_key, CTR + 1 mod 2^128) ||
-   AES(session_key, CTR + 2 mod 2^128) ...
-
-
-
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-   where the 128 bit value CTR is defined as follows:
-
-   CTR = (session_salt * 2^16) XOR (mux * 2^80) XOR (sender_id * 2^64)
-   XOR (sequence_number * 2^16)
-
-   where each of the four terms are padded with as many leading zeros to
-   form a 128 bit value.
-
-   Mind that the 16 least siginificant bits of CTR are zero.  These bits
-   are used for the counter.  Therefore the number of blocks generated
-   for one packet MUST NOT exceed 2^16 to avoid keystream reuse.  This
-   means that the packet length MUST NOT exceed 2^16 * 128 bits = 2^23
-   bits to ensure the security of the encryption.
-
-5.2.2.  Authentication and Integrity
-
-   It is RECOMMENDED to use an authentication tag and if it is used it
-   should be processed as follows.  The sender generates the tag over
-   the authenticated portion truncates it to the left-most (most
-   significant) bits to fit the authentication tag length signaled by
-   the key exchange mechanism.  After that it simple appends the tag to
-   the packet.  The receiver computes the tag in the same way as the
-   sender and compares if with the received tag.  If they don't match
-   the packet HAS TO be discarded and the incident SHOULD be logged.
-
-5.2.2.1.  HMAC-SHA1
-
-   This transform uses HMAC-SHA1 (as described in [RFC2104]) as message
-   authentication algorithm.  The identifier for the transfrom SHOULD be
-   SHA1 and it don't needs any transform specific parameters.  The key
-   should be derived using the key derivation pseudo random function:
-
-   session_auth_key = PRF_20(master_key, x)
-   with PRF and x defined as in Section 5.1.3
-
-5.2.3.  Key Derivation Pseudo Random Functions
-
-5.2.3.1.  AES in Counter Mode
-
-   Section 5.1.3 defines a pseudo random function which SHOULD be used
-   to derive session keys and salts.  This describes the use of AES in
-   counter mode as PRF.  The identifier for this PRF SHOULD be AES-CTR-
-   <key_length> or just AES-CTR in which case the key length defaults to
-   128 bits.  Beside the key length there are no additional transform
-   specific parameters.  This transform needs a master key of length
-   key_length and a 112 bit master salt.  The pseudo random string
-   consists of several segements with a size of 128 bits (AES
-   blocksize).  The whole string can be computed as follows:
-
-
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-   AES(master_key, CTR) || AES(master_key, CTR + 1 mod 2^128) ||
-   AES(master_key, CTR + 2 mod 2^128) ...
-
-   where the 128 bit value CTR is defined as x * 2^16, with x defined as
-   in Section 5.1.3.
-
-   This pseudo random function can produce pseudo random strings up to a
-   length of 2^23 bits.  If the requested output length n does not fit
-   multiples of 128 bits the output SHOULD be truncated to the n first
-   (left-most) bits.  Therefore there are n/128, rounded up,
-   applications of AES needed to produce the output string.
-
-5.3.  Adding SATP Transforms
-
-   If a new transform is to be added to SATP a standard track RFC MUST
-   be written to define the usage of the new transform.  Any overlap
-   between the new RFC and this document SHOULD be avoided but it MAY be
-   needed to update some of the information in this document.  For
-   example new parameters MAY be added to the cryptographic context or
-   there MAY be additional steps in SATP packet processing.
-
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-6.  Key Managment and Anycast Synchronization Considerations
-
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-7.  Security Considerations
-
-   As the cryptography of SATP is based on SRTP [RFC3711], it basically
-   shares the same security issues.  This section will only discuss some
-   small changes.  Please read SRTP RFC3711 section 9 [RFC3711] for
-   details.
-
-7.1.  Replay protection
-
-   Replay protection is done by a replay list.  Every anycast receiver
-   has its own replay list, which SHOULDN'T be syncronised because of
-   massive overhead.  This leads to an additional possible attack.  An
-   attacker is able to replay a captured packet once to every anycast
-   receiver.  This attack is considered be very unlikely because
-   multiple attack hosts in different locations are needed to reach
-   seperate anycast receivers and the number of replays is limited to
-   count of receivers - 1.  Such replays might also happen because of
-   routing problems, so a payload protocol HAS TO be robust against a
-   small number of duplicated packages.  The window size and position
-   HAS TO be syncronised between multiple anycast receivers to limit
-   this attack.
-
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-8.  IANA Considerations
-
-   The protocol is intended to be used on top of IP or on top of UDP (to
-   be compatible with NAT routers), so UDP and IP protocol numbers have
-   to be assiged by IANA.
-
-
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-9.  References
-
-9.1.  Normative References
-
-   [RFC3711]  Baugher, M., McGrew, D., Naslund, M., Carrara, E., and K.
-              Norrman, "The Secure Real-time Transport Protocol (SRTP)",
-              RFC 3711, March 2004.
-
-   [RFC2119]  Bradner, S., "Key words for use in RFCs to Indicate
-              Requirement Levels", BCP 14, RFC 2119, March 1997.
-
-   [RFC2003]  Perkins, C., "IP Encapsulation within IP", RFC 2003,
-              October 1996.
-
-   [RFC2104]  Krawczyk, H., Bellare, M., and R. Canetti, "HMAC: Keyed-
-              Hashing for Message Authentication", RFC 2104,
-              February 1997.
-
-9.2.  Informational References
-
-   [RFC2784]  Farinacci, D., Li, T., Hanks, S., Meyer, D., and P.
-              Traina, "Generic Routing Encapsulation (GRE)", RFC 2784,
-              March 2000.
-
-   [RFC2401]  Kent, S. and R. Atkinson, "Security Architecture for the
-              Internet Protocol", RFC 2401, November 1998.
-
-   [RFC1546]  Partridge, C., Mendez, T., and W. Milliken, "Host
-              Anycasting Service", RFC 1546, November 1993.
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-Authors' Addresses
-
-   Othmar Gsenger
-   Puerstingerstr 32
-   Saalfelden  5760
-   AT
-
-   Phone:
-   Email: satp@gsenger.com
-   URI:   http://www.gsenger.com/satp/
-
-
-   Christian Pointner
-   Wielandgasse 19
-   Graz  8010
-   AT
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-   Phone:
-   Email: equinox@anytun.org
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-
-Full Copyright Statement
-
-   Copyright (C) The IETF Trust (2009).
-
-   This document is subject to the rights, licenses and restrictions
-   contained in BCP 78, and except as set forth therein, the authors
-   retain all their rights.
-
-   This document and the information contained herein are provided on an
-   "AS IS" basis and THE CONTRIBUTOR, THE ORGANIZATION HE/SHE REPRESENTS
-   OR IS SPONSORED BY (IF ANY), THE INTERNET SOCIETY, THE IETF TRUST AND
-   THE INTERNET ENGINEERING TASK FORCE DISCLAIM ALL WARRANTIES, EXPRESS
-   OR IMPLIED, INCLUDING BUT NOT LIMITED TO ANY WARRANTY THAT THE USE OF
-   THE INFORMATION HEREIN WILL NOT INFRINGE ANY RIGHTS OR ANY IMPLIED
-   WARRANTIES OF MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE.
-
-
-Intellectual Property
-
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-   Intellectual Property Rights or other rights that might be claimed to
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-   might or might not be available; nor does it represent that it has
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-   on the procedures with respect to rights in RFC documents can be
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-   Copies of IPR disclosures made to the IETF Secretariat and any
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-   http://www.ietf.org/ipr.
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-   copyrights, patents or patent applications, or other proprietary
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-   this standard.  Please address the information to the IETF at
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diff --git a/papers/draft-gsenger-pointner-secure-anycast-tunneling-protocol-01.xml b/papers/draft-gsenger-pointner-secure-anycast-tunneling-protocol-01.xml
deleted file mode 100644
index a57f1b4..0000000
--- a/papers/draft-gsenger-pointner-secure-anycast-tunneling-protocol-01.xml
+++ /dev/null
@@ -1,527 +0,0 @@
-<?xml version='1.0'?>
-  <!DOCTYPE rfc SYSTEM 'rfcXXXX.dtd' [
-       
-  <!ENTITY rfc1546 PUBLIC '' 'http://xml.resource.org/public/rfc/bibxml/reference.RFC.1546.xml'>
-  <!ENTITY rfc3711 PUBLIC '' 'http://xml.resource.org/public/rfc/bibxml/reference.RFC.3711.xml'>
-  <!ENTITY rfc3068 PUBLIC '' 'http://xml.resource.org/public/rfc/bibxml/reference.RFC.3068.xml'>
-  <!ENTITY rfc2784 PUBLIC '' 'http://xml.resource.org/public/rfc/bibxml/reference.RFC.2784.xml'>
-  <!ENTITY rfc2401 PUBLIC '' 'http://xml.resource.org/public/rfc/bibxml/reference.RFC.2401.xml'>
-  <!ENTITY rfc2119 PUBLIC '' 'http://xml.resource.org/public/rfc/bibxml/reference.RFC.2119.xml'>
-  <!ENTITY rfc2003 PUBLIC '' 'http://xml.resource.org/public/rfc/bibxml/reference.RFC.2003.xml'>
-  <!ENTITY rfc2104 PUBLIC '' 'http://xml.resource.org/public/rfc/bibxml/reference.RFC.2104.xml'>
-]>
-<?rfc toc='yes'?>
-<rfc ipr='full3978' docName='draft-gsenger-pointner-secure-anycast-tunneling-protocol-01'>
-  <front>
-    <title>secure anycast tunneling protocol (SATP)</title>
-    <author initials='O.G.' surname='Gsenger' fullname='Othmar Gsenger'>
-      <organization></organization>
-      <address>
-        <postal>
-          <street>Puerstingerstr 32</street>
-          <city>Saalfelden</city>
-          <code>5760</code>
-          <country>AT</country>
-        </postal>
-        <phone></phone>
-        <email>satp@gsenger.com</email>
-        <uri>http://www.gsenger.com/satp/</uri>
-      </address>
-    </author>
-    <author initials='C.P.' surname='Pointner' fullname='Christian Pointner'>
-      <organization></organization>
-      <address>
-        <postal>
-          <street>Wielandgasse 19</street>
-          <city>Graz</city>
-          <code>8010</code>
-          <country>AT</country>
-        </postal>
-        <phone></phone>
-        <email>equinox@anytun.org</email>
-      </address>
-    </author>
-
-    <date month='April' year='2009' />
-
-    <area>General</area>
-    <workgroup></workgroup>
-    <keyword>satp</keyword>
-    <keyword>Internet-Draft</keyword>
-    <keyword>secure anycast tunneling protocol</keyword>
-    <keyword>anycast</keyword>
-    <keyword>tunnel</keyword>
-    <keyword>secure</keyword>
-    <keyword>protocol</keyword>
-
-    <abstract>
-      <t>
-        The secure anycast tunneling protocol (SATP) defines a protocol used for communication between any combination of unicast and anycast tunnel endpoints. It allows tunneling of every ETHER TYPE protocol (ethernet, ip ...). SATP directly includes cryptography and message authentication based on the methods used by the <xref target="RFC3711">Secure Real-time Transport Protocol(SRTP)</xref>. It can be used as an encrypted alternative to <xref target="RFC2003">IP Encapsulation within IP</xref> and <xref target="RFC2784">Generic Routing Encapsulation (GRE)</xref>. Both anycast receivers and senders are supported.
-      </t>
-    </abstract>
-  </front>
-
-  <middle>
-    <section title='Introduction'>
-      <t>
-        SATP is a mixture of a generic encapsulation protocol like <xref target="RFC2784">GRE</xref> and a secure tunneling protocol as <xref target="RFC2401">IPsec</xref> in tunnel mode.  It can be used to build redundant virtual private network (VPN) connections.  It supports peer-to-peer tunnels, where tunnel endpoints can be any combination of unicast, multicast or anycast hosts, so it defines a <xref target="RFC1546">Host Anycast Service</xref>. Encryption is done per packet, so the protocol is robust against packet loss and routing changes.
-To reduce header overhead, encryption techniques similar to <xref target="RFC3711">SRTP</xref> are being used.
-      </t>
-      <section title='Notational Conventions'>
-        <t>
-          The keywords "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT", "SHOULD", "SHOULD NOT", "RECOMMENDED", "MAY", and "OPTIONAL" in this document are to be interpreted as described in  <xref target="RFC2119">RFC2119</xref>.
-        </t>
-      </section>
-    </section> 
-    
-    <section title="Motivation and usage scenarios">
-      <t>
-        This section gives an overview of possible usage scenarios. Please note that the protocols used in the figures are only examples and that SATP itself does not care about either transport protocols or encapsulated protocols. Routing is not done by SATP and each implemetation MAY choose it's own way of doing this task (e.g. using functions provided by the operating system). SATP is used only to encapsulate and encrypt data.
-      </t>
-      <section title="Usage scenarions">
-        <section title='Tunneling from unicast hosts over anycast routers to other unicast hosts'>
-          <figure anchor="tunnel_mode">
-            <preamble>An example of SATP used to tunnel in a unicast client - anycast server model</preamble>
-            <artwork>
-                    --------- router ----------- 
-                   /                            \ 
-    unicast ------+---------- router ------------+------ unicast
-    host           \                            /        host
-                    --------- router -----------  
-
-  unicast  | encrypted     |  anycast  | encrypted     |  unicast
-  tunnel   | communication |  tunnel   | communication |  tunnel  
-  endpoint | using SATP    |  endpoint | using SATP    |  endpoint 
-            </artwork>
-          </figure>
-          <t>
-            In this scenario the payload is encapsuleted into a SATP packet by a unicast host and gets transmitted to one of the anycast routers. After transmisson the packet gets decapsulated by the router. This router makes a routing descision based on the underlying protocol and transmits a new SATP package to one or more unicast hosts depending on this decision.
-          </t> 
-        </section>
-        <section title='Tunneling from unicast hosts to anycast networks'>
-          <figure anchor="open_tunnel_mode">
-            <preamble>An example of SATP used to encrypt data between a unicast host and anycast networks</preamble>
-            <artwork>
-                       -------Router -+---- DNS Server
-                      /                \ 
-                     /                  --- 6to4 Router
-                    /
-    unicast -------+----------Router --+--- DNS Server
-    host            \                   \  
-                     \                   --- 6to4 Router
-                      \
-                       -------Router -+---- DNS Server
-                                       \
-                                        --- 6to4 Router
-
-  unicast  | encrypted     |  anycast  | plaintext
-  tunnel   | communication |  tunnel   | anycast
-  endpoint | using SATP    |  endpoint | services
-
-            </artwork>
-          </figure>
-          <t>
-            When the unicast hosts wants to transmit data to one of the anycast DNS servers, it encapsulates the data and sends a SATP packet to the anycast address of the routers. The packet arrives at one of the routers, gets decapsulated and is then forwarded to the DNS server. This method can be used to tunnel between clients and networks providing anycast services. It can also be used the other way to virtually locate a unicast service within anycasted networks.
-          </t>
-        </section>
-        <section title='Redundant tunnel connection of 2 networks'>
-          <figure anchor="connect_networks">
-            <preamble>An example of SATP used to connect 2 networks</preamble>
-            <artwork>
-              Router -----------   ---------------Router
-            /                   \ /                     \
-    Network - Router ------------x                       Network
-       A    \                   / \                     /   B
-              Router -----------   ---------------Router
-
-            | packets       |  packets  |  packets      |
- plaintext  | get           |  take a   |  get          | plaintext
- packets    | de/encrypted  |  random   |  de/encrypted | packets
-            |de/encapsulated|   path    |de/encapsulated|              
-
-            </artwork>
-          </figure>
-          <t>
-            Network A has multiple routers which act as gateway/tunnel endpoints to another network B. This way a redundant encrypted tunnel connection between the two networks is built up. All tunnel endpoints of network A share the same anycast address and all tunnel endpoints of network B share another anycast address. When a packet from network A is transmitted to network B, it first arrives on one of network A's border routers. Which router is used is determined by network A's internal routing. This router encapsulates the package and sends it to the anycast address of network B's routers. After arrival the SATP packet gets decapsulated and routed to its destination within network B.
-          </t>
-        </section>
-      </section>
-
-      <section title="Encapsulation">
-        <t>
-          SATP does not depend on the lower layer protocol. This section only gives an example of how packets could look like.
-        </t>
-        <figure anchor="transport_udp">
-          <preamble>Examples of SATP used with different lower layer and payload protocols</preamble>
-          <artwork>
-    +------+-----+-------------------------------+
-    |      |     |      +----------------+-----+ |
-    | IPv6 | UDP | SATP | Ethernet 802.3 | ... | |
-    |      |     |      +----------------+-----+ |
-    +------+-----+-------------------------------+
-
-Tunneling of Ethernet over UDP/IPv6
-
-    +------+-----+---------------------------+
-    |      |     |      +------+-----+-----+ |
-    | IPv4 | UDP | SATP | IPv6 | UDP | RTP | |
-    |      |     |      +------+-----+-----+ |
-    +------+-----+---------------------------+
-
-Tunneling of IPv6 over UDP/IPv4 with RTP payload
-
-    +------+-------------------------------+
-    |      |      +----------------+-----+ |
-    | IPv6 | SATP | Ethernet 802.3 | ... | |
-    |      |      +----------------+-----+ |
-    +------+-------------------------------+
-
-Tunneling of Ethernet over IPv6
-
-    +------+---------------------------+
-    |      |      +------+-----+-----+ |
-    | IPv4 | SATP | IPv6 | UDP | RTP | |
-    |      |      +------+-----+-----+ |
-    +------+---------------------------+
-
-Tunneling of IPv6 over IPv4 with RTP payload
-          </artwork>
-        </figure>
-      </section>
-    </section>
-
-    <section title="Using SATP on top of IP">
-      <section title="Fragmentation">
-        <t>
-          The only way of fully supporting fragmentation would be to synchronise fragments between all anycast servers. This is considered to be too much overhead, so there are two non-perfect solutions for these problems. Either fragmentation HAS TO be disabled or if not all fragments arrive at the same server the IP datagramm HAS TO be discarded. As routing changes are not expected to occur very frequently, the encapsulated protocol can do a retransmission and all fragments will arrive at the new server. 
-        </t>
-        <t>
-          If the payload type is IP and the IP headers' Don't Fragment (DF) bit is set, then the DF bit of the outer IP header HAS TO be set as well.
-        </t>
-      </section>
-      <section title="ICMP messages">
-        <t>
-          ICMP messages MUST be relayed according to <xref target="RFC2003">rfc2003 section 4</xref>. This is needed for path MTU detection.
-        </t>
-      </section>
-    </section>
-
-    <section title="Protocol specification">
-      <section title="Header format">
-        <figure anchor="prot_header_table">
-          <preamble>Protocol Format</preamble>
-          <artwork>
-   0                   1                   2                   3
-   0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
-  +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
-  |                         sequence number                       | |
-  +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ |
-  |           sender ID           |              MUX              | |
-+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+ |
-| |         payload type          |                               | |
-| +-------------------------------+                               | |
-| |              ....        payload        ...                   | |
-| |                               +-------------------------------+ |
-| |                               | padding (OPT) | pad count(OPT)| |
-+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+-+
-| :                 authentication tag (RECOMMENDED)              : |
-| +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ |
-|                                                                   |
-+- Encrypted Portion                       Authenticated Portion ---+
-          </artwork>
-        </figure>
-        <t></t>
-      </section>
-      <section title="sequence number">
-        <t>
-          The sequence number is a 32 bit unsigned integer in network byte order. The starting point is signaled by the key exchange mechanism and then value is then increased by 1 for every packet sent. After the maximum value it starts over from 0.
-        </t>
-      </section>
-      <section title="sender ID">
-        <t>
-          The sender ID is a 16 bit unsigned integer. It HAS TO be unique for every sender sharing the same anycast address.
-        </t>
-      </section>
-      <section title="MUX">
-        <t>
-          The MUX (multiplex) field is a 16 bit unsigned integer. It is used to distinguish multiple tunnel connections.
-        </t>
-      </section>
-      <section title="payload type">
-        <t>
-          The payload type field defines the payload protocol. ETHER TYPE protocol numbers are used. <eref target="http://www.iana.org/assignments/ethernet-numbers">See IANA assigned ethernet numbers</eref> . The values 0000-05DC are reserverd and MUST NOT be used. 
-          <figure anchor="prot_type_table">
-            <preamble>Some examples for protocol numbers</preamble>
-            <artwork>
-HEX
-0000 Reserved
-.... Reserved
-05DC Reserved
-0800 Internet IP (IPv4)
-6558 transparent ethernet bridging
-86DD IPv6
-            </artwork>
-          </figure>
-        </t>
-      </section>
-      <section title="payload">
-        <t>
-          A packet of type payload type (e.g. an IP packet).
-        </t>
-      </section>
-      <section title="padding (OPTIONAL)">
-        <t>
-          Padding of max 255 octets. None of the pre-defined encryption transforms uses any padding; for these, the plaintext and encrypted payload sizes match exactly. Transforms which may be added in future (see <xref target="sec_adding_transform" />) MUST define wheter they need padding or not and if they need it they MUST define a proper padding format. If the padding count field is present, the padding count field MUST be set to the padding length.
-        </t>
-      </section>
-      <section title="padding count (OPTIONAL)">
-        <t>
-          The number of octets of the padding field. This field is optional. Its presence is signaled by the key management and not by this protocol. If this field isn't present, the padding field MUST NOT be present as well.
-        </t>
-      </section>
-      <section title="authentication tag (RECOMMENDED)">
-        <t>
-          The authentication tag is RECOMMENDED and of configurable length. It contains a cryptographic checksum of the sender ID, sequence number and the encrypted portion. On transmitter side encryption HAS TO be done before calculating the authentication tag. A receiver HAS TO calculate the authentication tag before decrypting the encrypted portion.
-        </t>
-      </section>
-    </section>
-
-    <section title="Cryptography">
-      <t>
-        As mentioned earlier the cryptography of SATP is based on <xref target="RFC3711">SRTP</xref>. For that reason we recommend to read this document as well (especially chapter 7 Rationale). However some modifications were made in order to fit the changed conditions of SATP. The following section describes the whole cryptography of SATP.
-      </t>
-      <section title="Basic Concepts">
-        <t>
-          In order to cope with anycast and packet loss it is important to be able to process one packet on its own without the need for packets from the past as an additional information source. Therefore SATP as well as <xref target="RFC3711">SRTP</xref> defines a so called cryptographic context. This context consits of all information which is needed to process a single SATP packet and is divided into packet specific parameters and global parameters. The packet specific parameters can be found in the protocol header and global parameters have to be generated by the key exchange mechanism external to SATP (see <xref target="sec_key_mgmt" />). For anycast sender the global parameters have to be synchronized between all hosts which share the same anycast address. The packet specific parameters MUST NOT be synchronized.<vspace blankLines="0" />
-SATP uses two types of keys: master keys and session keys. A session key is meant to be used for a cryptographic transform (encrytion or message authentication) for one packet. The master keys are used to derive packet-specific session keys in a cryptographical secure way.
-        </t>
-        <section title="Cryptographic Contexts">
-          <section title="Global Parameters">
-            <t>
-              As mentioned above global parameters HAVE TO either be provided by the key exchange mechanism or configured manually.
-              <list style="symbols">
-                <t>a master key(s) which MUST be random and kept secret.</t>
-                <t>a master salt which MUST be random and MAY be public (RECOMMENDED to be kept secret as well).</t>
-                <t>a role specifier used by the key derivation to determine which session keys to generate for outbound or inbound traffic.</t>
-                <t>identifier for the key derivation pseudo random function.</t>
-                <t>identifier for the encryption algorithm (i.e. cipher and its mode of operation).</t>
-                <t>if used an identifier for the authentication algorithm.</t>
-                <t>transform specific parameters such as key lengths, see <xref target="sec_pref_transform"/>.</t>
-                <t>if used the length of the authentication tag which should be truncated to the packet.</t>
-                <t>an indicator which specifies if padding is needed or not (presence of padding count field).</t>
-                <t>a replay list for each sender (see <xref target="sec_mapping_context" />), maintained by the receiver which contains the sequence numbers of received and authenticated packets, this lists may be implemented as a sliding window.</t>
-                <t>a [ From , To ] value pair which specifies the lifetime of a master key (including the range endpoints), expressed in terms of a pair of 32-bit sequence numbers.</t>
-              </list>
-            </t>
-          </section>
-          <section title="Packet-Specific Parameters">
-            <t>
-              <list style="symbols">
-                <t>the sequence number</t>
-                <t>the sender id</t>
-                <t>the mux value</t>
-              </list>
-            </t>
-          </section>
-          <section title="Mapping SATP packets to Cryptographic Contexts" anchor="sec_mapping_context">
-            <t>
-              A cryptographic contexts SHALL be uniquely identifed by the tuple context identifier:
-              <vspace blankLines="1" />
-              context id = [ source address , source port ]
-              <vspace blankLines="1" />
-              In order to cope with anycast sender and replay protection there HAS TO be more than one replay list per context. Each replay list inside a cryptographic context SHALL be uniquely identified by the sender id.<vspace blankLines="0" />
-              
-            </t>
-          </section>
-        </section>
-        <section title="SATP Packet Processing">
-          <t>
-            Before any SATP packet can be processed a cryptographic context HAS TO be initialized by the key management mechanism. After that a SATP sender SHALL do the following to create a SATP packet:
-            <list style="numbers">
-              <t>Determine the next sequence number to use.</t>
-              <t>Determine the crypotgraphic context as described in <xref target="sec_mapping_context" />.</t>
-              <t>Determine the master key and master salt for the packets sequence number.</t>
-              <t>Compute all session keys and session salts which are needed by the encryption transform using the key derivation pseudo random function.</t>
-              <t>Encrypt the payload type field concatenated with the payload to produce the encrypted portion of the packet using the encryption algorithm defined by the cryptographic context.</t>
-              <t>Fill in sender id, mux and sequence number fields.</t>
-              <t>If needed compute the session authentication key using the key derivation pseudo random function.</t>
-              <t>Generate the authentication tag over the authenticated portion using the authentication algorithm defined by the cryptographic context and append it to the packet.</t>
-            </list>
-            On receiver side the packet SHALL be processed as follows:
-            <list style="numbers">
-              <t>Determine the crypotgraphic context as described in <xref target="sec_mapping_context" />.</t>
-              <t>Determine the master key and master salt for the packets sequence number.</t>
-              <t>Check if the packet was replayed using the replay list for the packets sender id.</t>
-              <t>If needed compute the session authentication key using the key derivation pseudo random function.</t>
-              <t>Generate the authentication tag over the authenticated portion using the authentication algorithm defined by the crpyptographic context and compare it with the tag appended to the received packet. If it is equal remove the tag and move on. If it is not equal drop the packet.</t>
-              <t>Store the sequence number in the replay list.</t>
-              <t>Compute all session keys and session salts which are needed by the encryption transform using the key derivation pseudo random function.</t>
-              <t>Decrypt the encrypted portion using the encryption algorithm defined by the cryptographic context.</t>
-              <t>Check if the payload type is supported by this tunnel endpoint and discard the packet in case it isn't supported.</t>
-              <t>Remove all fields beside the payload itself from the packet.</t>
-            </list>
-          </t>
-        </section>
-        <section title="Key derivation" anchor="sec_key_derivation">
-          <t>
-            Any encryption or message authentication transform which is used (predefined or newly introduced according to <xref target="sec_adding_transform" />) MUST obtain its secret values (keys and salts) using the SATP key derivation. After the key exchange mechanism has signaled all needed parameters (i.e. master key and salt) no additional communiction between sender and receiver is needed until the next rekeying takes place. To achieve this the key derivation uses an pseudo random function seeded by the master key, master salt, the packets sequence number and a label (identifier for the key to compute).
-          </t>
-          <figure anchor="key_derivation">
-            <preamble>SATP key derivation</preamble>            
-            <artwork>
-   packet sequence nummber ----+
-                               |
-                               V
-  +------------+ master +------------+
-  |            | key    |            |--> session encryption key
-  | ext. key   |------->| key        |
-  | management |        |            |--> session encryption salt
-  | mechanism  |------->| derivation |
-  |            | master |            |--> session authentication key
-  +------------+ salt   +------------+
-            </artwork>
-          </figure>
-          <t>
-            <xref target="RFC3711">SRTP</xref> defines a pseudo random function as follows: <vspace blankLines="0" />
-            Let m and n be positive integers. A pseudo-random function family is a set of keyed functions {PRF_n(k,x)} such that for the (secret) random key k, given m-bit x, PRF_n(k,x) is an n-bit string, computationally indistinguishable from random n-bit strings.<vspace blankLines="1" />
-            For SATP key generation a pseudo random function with at least m = 128 MUST be used. A predefined transform can be found in <xref target="sec_pref_kdprf" />.
-            The input x of the PRF SHOULD be calculated as follows:
-            <list style="numbers">
-              <t>Let key_id = label || sequence_number, with label defined as below.</t>
-              <t>Let x = key_id XOR master_salt, where key_id and master_salt are aligend so that their least significant bits agree (right-alignment).</t>
-            </list>
-            For each key derived by the key derivation there MUST exist a unique label, a 32-bit constant. In order to increase security SATP uses different session keys for inbound and outbound traffic. The role specifier from the cryptographic context is used to determine which session keys to use for inbound and outbound packets.
-            The labels can be computed by calculateing the SHA1 hash over an increasing label-index. The label value are the 32 leftmost bits of this hash value.
-            We currently define 6 labels (label-index from 1 to 6) future extensions may use labels with an index from 7 upwards.
-          </t>
-          <texttable title="Key Derivation Labels">
-            <ttcol align="left">key type</ttcol>
-            <ttcol align="left">role</ttcol>
-            <ttcol align="center">label-index</ttcol>
-            <ttcol align="center">label</ttcol>
-            <c>encryption key</c>
-            <c>left</c>
-            <c>1</c>
-            <c>0x356A192B</c>
-            <c>encryption key</c>
-            <c>right</c>
-            <c>2</c>
-            <c>0xDA4B9237</c>
-            <c>encryption salt</c>
-            <c>left</c>
-            <c>3</c>
-            <c>0x77DE68DA</c>
-            <c>encryption salt</c>
-            <c>right</c>
-            <c>4</c>
-            <c>0x1B645389</c>
-            <c>authentication key</c>
-            <c>left</c>
-            <c>5</c>
-            <c>0xAC3478D6</c>
-            <c>authentication key</c>
-            <c>right</c>
-            <c>6</c>
-            <c>0xC1DFD96E</c>
-          </texttable>
-          <t>
-            The role parameter specifies which label should be used for outbound packets. This means a endpoint with role left MUST use the labels marked with left for outgoing packets and expects inbound packets to be encrypted/authenticated using the labels marked with right.
-          </t>
-        </section>
-      </section>
-      <section title="Predefined Transforms" anchor="sec_pref_transform">
-        <t>
-          While SATP as well as SRTP allows the use of various encryption and message authentication algorithms interoperable implementations MUST support at least the following transforms. To add additional transforms see <xref target="sec_adding_transform" />.
-        </t>
-        <section title="Encryption">
-          <section title="NULL Encryption">
-            <t>
-              If confidendtiality of the SATP packet is not an issue the null encryption transform can be used to increase performance. This transform just copies the plaintext input into the ciphertext output wihtout any padding. The identifier for that transfrom SHOULD be NULL and it don't needs any transform specific parameters. It also doesn't need any key or salt values computed by the key derivation.
-            </t>
-          </section>
-          <section title="AES in Counter Mode">
-            <t>
-              The following describes how to use AES in counter mode for SATP encryption. The identifier for that transform SHOULD be AES-CTR-&lt;key_length&gt; or just AES-CTR in which case the key length defaults to 128 bits. Beside the key length there are no additional transfrom specific parameters. This transform needs a key of length &lt;key_length&gt; and a 112 bit salt. These values can be generated using the key derivation pseudo random function as follows:<vspace blankLines="1" />
-              session_key = PRF_&lt;key_length&gt;(master_key, x)<vspace blankLines="0" />
-              session_salt = PRF_112(master_key, x)<vspace blankLines="0" />
-              with PRF and x defined as in <xref target="sec_key_derivation" />.<vspace blankLines="1" />
-              Basically AES in counter mode generates a pseudo random keystream seeded by the session key, session salt as well as the sequence number, sender id and mux value of the packet and encrypts a single SATP packet using this stream. The encryption process consits of the generation of that keystream and then bitwise exclusive-oring it onto the packets payload. If the packet length doesn't fit a multiple of 128 bits the remaining bits (least significant) of the keystream are simple ingored. Therefore this transform does not need any padding. Decryption of the packet can be achieved by generating the same keystream and exclusive-oring it onto the encrypted portion. 
-            </t>
-            <section title="Keystream Generation">
-              <t>
-                In principle AES in counter mode consists of encrypting an incrementing integer. However the starting point of the integer value has to be randomized to get a good pseudo random key stream. A keystream consits of several keystream segements with a size of 128 bits (AES blocksize). Each segement can be computed by applying AES with key k on the block CTR. The whole keystream is a concatination of all its successive segements. Therefore a keystream looks as follows:<vspace blankLines="1" />
-                AES(session_key, CTR) || AES(session_key, CTR + 1 mod 2^128) || AES(session_key, CTR + 2 mod 2^128) ...<vspace blankLines="1" />
-                where the 128 bit value CTR is defined as follows:<vspace blankLines="1" />
-                CTR = (session_salt * 2^16) XOR (mux * 2^80) XOR (sender_id * 2^64) XOR (sequence_number * 2^16)<vspace blankLines="1" />
-                where each of the four terms are padded with as many leading zeros to form a 128 bit value.
-              </t>
-              <t>
-                Mind that the 16 least siginificant bits of CTR are zero. These bits are used for the counter. Therefore the number of blocks generated for one packet MUST NOT exceed 2^16 to avoid keystream reuse. This means that the packet length MUST NOT exceed 2^16 * 128 bits = 2^23 bits to ensure the security of the encryption.
-              </t>
-            </section>
-          </section>
-        </section>
-        <section title="Authentication and Integrity">
-          <t>
-            It is RECOMMENDED to use an authentication tag and if it is used it should be processed as follows. The sender generates the tag over the authenticated portion truncates it to the left-most (most significant) bits to fit the authentication tag length signaled by the key exchange mechanism. After that it simple appends the tag to the packet. The receiver computes the tag in the same way as the sender and compares if with the received tag. If they don't match the packet HAS TO be discarded and the incident SHOULD be logged.
-          </t>
-          <section title="HMAC-SHA1">
-            <t>
-              This transform uses HMAC-SHA1 (as described in <xref target="RFC2104" />) as message authentication algorithm. The identifier for the transfrom SHOULD be SHA1 and it don't needs any transform specific parameters. The key should be derived using the key derivation pseudo random function:<vspace blankLines="1" />
-              session_auth_key = PRF_20(master_key, x)<vspace blankLines="0" />
-              with PRF and x defined as in <xref target="sec_key_derivation" />
-            </t>
-          </section>
-        </section>
-        <section title="Key Derivation Pseudo Random Functions" anchor="sec_pref_kdprf">
-          <section title="AES in Counter Mode">
-            <t>
-              <xref target="sec_key_derivation" /> defines a pseudo random function which SHOULD be used to derive session keys and salts. This describes the use of AES in counter mode as  PRF. The identifier for this PRF SHOULD be AES-CTR-&lt;key_length&gt; or just AES-CTR in which case the key length defaults to 128 bits. Beside the key length there are no additional transform specific parameters. This transform needs a master key of length key_length and a 112 bit master salt. The pseudo random string consists of several segements with a size of 128 bits (AES blocksize). The whole string can be computed as follows:<vspace blankLines="1" />
-              AES(master_key, CTR) || AES(master_key, CTR + 1 mod 2^128) || AES(master_key, CTR + 2 mod 2^128) ...<vspace blankLines="1" />
-              where the 128 bit value CTR is defined as x * 2^16, with x defined as in <xref target="sec_key_derivation" />.<vspace blankLines="1" />
-              This pseudo random function can produce pseudo random strings up to a length of 2^23 bits. If the requested output length n does not fit multiples of 128 bits the output SHOULD be truncated to the n first (left-most) bits. Therefore there are n/128, rounded up, applications of AES needed to produce the output string.
-            </t>
-          </section>
-        </section>
-      </section>
-      <section title="Adding SATP Transforms" anchor="sec_adding_transform">
-        <t>
-          If a new transform is to be added to SATP a standard track RFC MUST be written to define the usage of the new transform. Any overlap between the new RFC and this document SHOULD be avoided but it MAY be needed to update some of the information in this document. For example new parameters MAY be added to the cryptographic context or there MAY be additional steps in SATP packet processing.
-        </t>
-      </section>
-    </section>
-    
-    <section title="Key Managment and Anycast Synchronization Considerations" anchor="sec_key_mgmt">
-    </section>
-
-    <section title="Security Considerations">
-      <t>
-        As the cryptography of SATP is based on <xref target="RFC3711">SRTP</xref>, it basically shares the same security issues. This section will only discuss some small changes. Please read <xref target="RFC3711">SRTP RFC3711 section 9</xref> for details.
-      </t>
-      <section title="Replay protection">
-        <t>
-          Replay protection is done by a replay list. Every anycast receiver has its own replay list, which SHOULDN'T be syncronised because of massive overhead. This leads to an additional possible attack. An attacker is able to replay a captured packet once to every anycast receiver. This attack is considered be very unlikely because multiple attack hosts in different locations are needed to reach seperate anycast receivers and the number of replays is limited to count of receivers - 1. Such replays might also happen because of routing problems, so a payload protocol HAS TO be robust against a small number of duplicated packages. The window size and position HAS TO be syncronised between multiple anycast receivers to limit this attack.
-        </t>
-      </section>
-    </section>
-
-    <section title="IANA Considerations">
-      <t>
-        The protocol is intended to be used on top of IP or on top of UDP (to be compatible with NAT routers), so UDP and IP protocol numbers have to be assiged by IANA.
-      </t>
-    </section>
-  </middle>
-  <back>
-    <references title="Normative References">
-      &rfc3711;
-      &rfc2119;
-      &rfc2003;
-      &rfc2104;
-    </references>
-    <references title="Informational References">
-      &rfc2784; 
-      &rfc2401;
-      &rfc1546;
-    </references>
-  </back>
-</rfc>
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-<table summary="layout" cellpadding="0" cellspacing="2" class="TOCbug" align="right"><tr><td class="TOCbug"><a href="#toc">&nbsp;TOC&nbsp;</a></td></tr></table>
-<table summary="layout" width="66%" border="0" cellpadding="0" cellspacing="0"><tr><td><table summary="layout" width="100%" border="0" cellpadding="2" cellspacing="1">
-<tr><td class="header">Network Working Group</td><td class="header">O. Gsenger</td></tr>
-<tr><td class="header">Internet-Draft</td><td class="header">May 2008</td></tr>
-<tr><td class="header">Expires: November 2, 2008</td><td class="header">&nbsp;</td></tr>
-</table></td></tr></table>
-<h1><br />secure anycast tunneling protocol (SATP)<br />draft-gsenger-secure-anycast-tunneling-protocol-02</h1>
-
-<h3>Status of this Memo</h3>
-<p>
-By submitting this Internet-Draft,
-each author represents that any applicable patent or other IPR claims of which
-he or she is aware have been or will be disclosed,
-and any of which he or she becomes aware will be disclosed,
-in accordance with Section&nbsp;6 of BCP&nbsp;79.</p>
-<p>
-Internet-Drafts are working documents of the Internet Engineering
-Task Force (IETF), its areas, and its working groups.
-Note that other groups may also distribute working documents as
-Internet-Drafts.</p>
-<p>
-Internet-Drafts are draft documents valid for a maximum of six months
-and may be updated, replaced, or obsoleted by other documents at any time.
-It is inappropriate to use Internet-Drafts as reference material or to cite
-them other than as &ldquo;work in progress.&rdquo;</p>
-<p>
-The list of current Internet-Drafts can be accessed at
-<a href='http://www.ietf.org/ietf/1id-abstracts.txt'>http://www.ietf.org/ietf/1id-abstracts.txt</a>.</p>
-<p>
-The list of Internet-Draft Shadow Directories can be accessed at
-<a href='http://www.ietf.org/shadow.html'>http://www.ietf.org/shadow.html</a>.</p>
-<p>
-This Internet-Draft will expire on November 2, 2008.</p>
-
-<h3>Abstract</h3>
-
-<p>The secure anycast tunneling protocol (SATP) defines a protocol used for communication between any combination of unicast and anycast tunnel endpoints. It allows tunneling of every ETHER TYPE protocol (ethernet, ip ...). SATP directly includes cryptography and message authentication based on the methods used by the <a class='info' href='#RFC3711'>Secure Real-time Transport Protocol(SRTP)<span> (</span><span class='info'>Baugher, M., McGrew, D., Naslund, M., Carrara, E., and K. Norrman, &ldquo;The Secure Real-time Transport Protocol (SRTP),&rdquo; March&nbsp;2004.</span><span>)</span></a> [RFC3711]. It can be used as an encrypted alternative to <a class='info' href='#RFC2003'>IP Encapsulation within IP<span> (</span><span class='info'>Perkins, C., &ldquo;IP Encapsulation within IP,&rdquo; October&nbsp;1996.</span><span>)</span></a> [RFC2003] and <a class='info' href='#RFC2784'>Generic Routing Encapsulation (GRE)<span> (</span><span class='info'>Farinacci, D., Li, T., Hanks, S., Meyer, D., and P. Traina, &ldquo;Generic Routing Encapsulation (GRE),&rdquo; March&nbsp;2000.</span><span>)</span></a> [RFC2784]. Both anycast receivers and senders are supported.
-            
-</p><a name="toc"></a><br /><hr />
-<h3>Table of Contents</h3>
-<p class="toc">
-<a href="#anchor1">1.</a>&nbsp;
-Introduction<br />
-&nbsp;&nbsp;&nbsp;&nbsp;<a href="#anchor2">1.1.</a>&nbsp;
-Notational Conventions<br />
-<a href="#anchor3">2.</a>&nbsp;
-Motivation and usage scenarios<br />
-&nbsp;&nbsp;&nbsp;&nbsp;<a href="#anchor4">2.1.</a>&nbsp;
-Usage scenarions<br />
-&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;<a href="#anchor5">2.1.1.</a>&nbsp;
-Tunneling from unicast hosts over anycast routers to other unicast hosts<br />
-&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;<a href="#anchor6">2.1.2.</a>&nbsp;
-Tunneling from unicast hosts to anycast networks<br />
-&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;<a href="#anchor7">2.1.3.</a>&nbsp;
-Redundant tunnel connection of 2 networks<br />
-&nbsp;&nbsp;&nbsp;&nbsp;<a href="#anchor8">2.2.</a>&nbsp;
-Encapsulation<br />
-<a href="#anchor9">3.</a>&nbsp;
-Using SATP on top of IP<br />
-&nbsp;&nbsp;&nbsp;&nbsp;<a href="#anchor10">3.1.</a>&nbsp;
-Fragmentation<br />
-&nbsp;&nbsp;&nbsp;&nbsp;<a href="#anchor11">3.2.</a>&nbsp;
-ICMP messages<br />
-<a href="#anchor12">4.</a>&nbsp;
-Protocol specification<br />
-&nbsp;&nbsp;&nbsp;&nbsp;<a href="#anchor13">4.1.</a>&nbsp;
-Header format<br />
-&nbsp;&nbsp;&nbsp;&nbsp;<a href="#anchor14">4.2.</a>&nbsp;
-sequence number<br />
-&nbsp;&nbsp;&nbsp;&nbsp;<a href="#anchor15">4.3.</a>&nbsp;
-sender ID<br />
-&nbsp;&nbsp;&nbsp;&nbsp;<a href="#anchor16">4.4.</a>&nbsp;
-MUX<br />
-&nbsp;&nbsp;&nbsp;&nbsp;<a href="#anchor17">4.5.</a>&nbsp;
-payload type<br />
-&nbsp;&nbsp;&nbsp;&nbsp;<a href="#anchor18">4.6.</a>&nbsp;
-payload<br />
-&nbsp;&nbsp;&nbsp;&nbsp;<a href="#anchor19">4.7.</a>&nbsp;
-padding (OPTIONAL)<br />
-&nbsp;&nbsp;&nbsp;&nbsp;<a href="#anchor20">4.8.</a>&nbsp;
-padding count (OPTIONAL)<br />
-&nbsp;&nbsp;&nbsp;&nbsp;<a href="#anchor21">4.9.</a>&nbsp;
-MKI (OPTIONAL)<br />
-&nbsp;&nbsp;&nbsp;&nbsp;<a href="#anchor22">4.10.</a>&nbsp;
-authentication tag (RECOMMENDED)<br />
-&nbsp;&nbsp;&nbsp;&nbsp;<a href="#anchor23">4.11.</a>&nbsp;
-Encryption<br />
-<a href="#anchor24">5.</a>&nbsp;
-Security Considerations<br />
-&nbsp;&nbsp;&nbsp;&nbsp;<a href="#anchor25">5.1.</a>&nbsp;
-Replay protection<br />
-<a href="#anchor26">6.</a>&nbsp;
-IANA Considerations<br />
-<a href="#rfc.references1">7.</a>&nbsp;
-References<br />
-&nbsp;&nbsp;&nbsp;&nbsp;<a href="#rfc.references1">7.1.</a>&nbsp;
-Normative References<br />
-&nbsp;&nbsp;&nbsp;&nbsp;<a href="#rfc.references2">7.2.</a>&nbsp;
-Informational References<br />
-<a href="#rfc.authors">&#167;</a>&nbsp;
-Author's Address<br />
-<a href="#rfc.copyright">&#167;</a>&nbsp;
-Intellectual Property and Copyright Statements<br />
-</p>
-<br clear="all" />
-
-<a name="anchor1"></a><br /><hr />
-<table summary="layout" cellpadding="0" cellspacing="2" class="TOCbug" align="right"><tr><td class="TOCbug"><a href="#toc">&nbsp;TOC&nbsp;</a></td></tr></table>
-<a name="rfc.section.1"></a><h3>1.&nbsp;
-Introduction</h3>
-
-<p>SATP is a mixture of a generic encapsulation protocol like <a class='info' href='#RFC2784'>GRE<span> (</span><span class='info'>Farinacci, D., Li, T., Hanks, S., Meyer, D., and P. Traina, &ldquo;Generic Routing Encapsulation (GRE),&rdquo; March&nbsp;2000.</span><span>)</span></a> [RFC2784] and a secure tunneling protocol as <a class='info' href='#RFC2401'>IPsec<span> (</span><span class='info'>Kent, S. and R. Atkinson, &ldquo;Security Architecture for the Internet Protocol,&rdquo; November&nbsp;1998.</span><span>)</span></a> [RFC2401] in tunnel mode.  It can be used to build redundant virtual private network (VPN) connections.  It supports peer-to-peer tunnels, where tunnel endpoints can be any combination of unicast, multicast or anycast hosts, so it defines a <a class='info' href='#RFC1546'>Host Anycast Service<span> (</span><span class='info'>Partridge, C., Mendez, T., and W. Milliken, &ldquo;Host Anycasting Service,&rdquo; November&nbsp;1993.</span><span>)</span></a> [RFC1546]. Encryption is done per packet, so the protocol is robust against packet loss and routing changes.
-				To reduce header overhead, encryption techniques of <a class='info' href='#RFC3711'>SRTP<span> (</span><span class='info'>Baugher, M., McGrew, D., Naslund, M., Carrara, E., and K. Norrman, &ldquo;The Secure Real-time Transport Protocol (SRTP),&rdquo; March&nbsp;2004.</span><span>)</span></a> [RFC3711] are being used. 
-				
-</p>
-<a name="anchor2"></a><br /><hr />
-<table summary="layout" cellpadding="0" cellspacing="2" class="TOCbug" align="right"><tr><td class="TOCbug"><a href="#toc">&nbsp;TOC&nbsp;</a></td></tr></table>
-<a name="rfc.section.1.1"></a><h3>1.1.&nbsp;
-Notational Conventions</h3>
-
-<p>The keywords "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT", "SHOULD", "SHOULD NOT", "RECOMMENDED", "MAY", and "OPTIONAL" in this document are to be interpreted as described in  <a class='info' href='#RFC2119'>RFC2119<span> (</span><span class='info'>Bradner, S., &ldquo;Key words for use in RFCs to Indicate Requirement Levels,&rdquo; March&nbsp;1997.</span><span>)</span></a> [RFC2119].
-</p>
-<a name="anchor3"></a><br /><hr />
-<table summary="layout" cellpadding="0" cellspacing="2" class="TOCbug" align="right"><tr><td class="TOCbug"><a href="#toc">&nbsp;TOC&nbsp;</a></td></tr></table>
-<a name="rfc.section.2"></a><h3>2.&nbsp;
-Motivation and usage scenarios</h3>
-
-<p>This section gives an overview of possible usage scenarios. Please note that the protocols used in the figures are only examples and that SATP itself does not care about either transport protocols or encapsulated protocols. Routing is not done by SATP and each implemetation MAY choose it's own way of doing this task (e.g. using functions provided by the operating system). SATP is used only to encapsulate and encrypt data.
-</p>
-<a name="anchor4"></a><br /><hr />
-<table summary="layout" cellpadding="0" cellspacing="2" class="TOCbug" align="right"><tr><td class="TOCbug"><a href="#toc">&nbsp;TOC&nbsp;</a></td></tr></table>
-<a name="rfc.section.2.1"></a><h3>2.1.&nbsp;
-Usage scenarions</h3>
-
-<a name="anchor5"></a><br /><hr />
-<table summary="layout" cellpadding="0" cellspacing="2" class="TOCbug" align="right"><tr><td class="TOCbug"><a href="#toc">&nbsp;TOC&nbsp;</a></td></tr></table>
-<a name="rfc.section.2.1.1"></a><h3>2.1.1.&nbsp;
-Tunneling from unicast hosts over anycast routers to other unicast hosts</h3>
-<br /><hr class="insert" />
-<a name="tunnel_mode"></a>
-
-<p>An example of SATP used to tunnel in a unicast client - anycast server model
-</p><div style='display: table; width: 0; margin-left: 3em; margin-right: auto'><pre>
-                    --------- router -----------
-                   /                            \
-    unicast ------+---------- router ------------+------ unicast
-    host           \                            /        host
-                    --------- router -----------
-
-  unicast  | encrypted     |  anycast  | encrypted     |  unicast
-  tunnel   | communication |  tunnel   | communication |  tunnel
-  endpoint | using SATP    |  endpoint | using SATP    |  endpoint
-</pre></div><table border="0" cellpadding="0" cellspacing="2" align="center"><tr><td align="center"><font face="monaco, MS Sans Serif" size="1"><b>&nbsp;Figure&nbsp;1&nbsp;</b></font><br /></td></tr></table><hr class="insert" />
-
-<p>In this scenario the payload is encapsuleted into a SATP packet by a unicast host and gets transmitted to one of the anycast routers. After transmisson the packet gets decapsulated by the router. This router makes a routing descision based on the underlying protocol and transmits a new SATP package to one or more unicast hosts depending on this decision.
-</p>
-<a name="anchor6"></a><br /><hr />
-<table summary="layout" cellpadding="0" cellspacing="2" class="TOCbug" align="right"><tr><td class="TOCbug"><a href="#toc">&nbsp;TOC&nbsp;</a></td></tr></table>
-<a name="rfc.section.2.1.2"></a><h3>2.1.2.&nbsp;
-Tunneling from unicast hosts to anycast networks</h3>
-<br /><hr class="insert" />
-<a name="open_tunnel_mode"></a>
-
-<p>An example of SATP used to encrypt data between a unicast host and anycast networks
-</p><div style='display: table; width: 0; margin-left: 3em; margin-right: auto'><pre>
-                       -------Router -+---- DNS Server
-                      /                \
-                     /                  --- 6to4 Router
-                    /
-    unicast -------+----------Router --+--- DNS Server
-    host            \                   \
-                     \                   --- 6to4 Router
-                      \
-                       -------Router -+---- DNS Server
-                                       \
-                                        --- 6to4 Router
-
-  unicast  | encrypted     |  anycast  | plaintext
-  tunnel   | communication |  tunnel   | anycast
-  endpoint | using SATP    |  endpoint | services
-
-</pre></div><table border="0" cellpadding="0" cellspacing="2" align="center"><tr><td align="center"><font face="monaco, MS Sans Serif" size="1"><b>&nbsp;Figure&nbsp;2&nbsp;</b></font><br /></td></tr></table><hr class="insert" />
-
-<p>When the unicast hosts wants to transmit data to one of the anycast DNS servers, it encapsulates the data and sends a SATP packet to the anycast address of the routers. The packet arrives at one of the routers, gets decapsulated and is then forwarded to the DNS server. This method can be used to tunnel between clients and networks providing anycast services. It can also be used the other way to virtually locate a unicast service within anycasted networks.
-</p>
-<a name="anchor7"></a><br /><hr />
-<table summary="layout" cellpadding="0" cellspacing="2" class="TOCbug" align="right"><tr><td class="TOCbug"><a href="#toc">&nbsp;TOC&nbsp;</a></td></tr></table>
-<a name="rfc.section.2.1.3"></a><h3>2.1.3.&nbsp;
-Redundant tunnel connection of 2 networks</h3>
-<br /><hr class="insert" />
-<a name="connect_networks"></a>
-
-<p>An example of SATP used to connect 2 networks
-</p><div style='display: table; width: 0; margin-left: 3em; margin-right: auto'><pre>
-              Router -----------   ---------------Router
-            /                   \ /                     \
-    Network - Router ------------x                       Network
-       A    \                   / \                     /   B
-              Router -----------   ---------------Router
-
-            | packets       |  packets  |  packets      |
- plaintext  | get           |  take a   |  get          | plaintext
- packets    | de/encrypted  |  random   |  de/encrypted | packets
-            |de/encapsulated|   path    |de/encapsulated|
-
-</pre></div><table border="0" cellpadding="0" cellspacing="2" align="center"><tr><td align="center"><font face="monaco, MS Sans Serif" size="1"><b>&nbsp;Figure&nbsp;3&nbsp;</b></font><br /></td></tr></table><hr class="insert" />
-
-<p>Network A has multiple routers which act as gateway/tunnel endpoints to another network B. This way a redundant encrypted tunnel connection between the two networks is built up. All tunnel endpoints of network A share the same anycast address and all tunnel endpoints of network B share another anycast address. When a packet from network A is transmitted to network B, it first arrives on one of network A's border routers. Which router is used is determined by network A's internal routing. This router encapsulates the package and sends it to the anycast address of network B's routers. After arrival the SATP packet gets decapsulated and routed to its destination within network B.
-</p>
-<a name="anchor8"></a><br /><hr />
-<table summary="layout" cellpadding="0" cellspacing="2" class="TOCbug" align="right"><tr><td class="TOCbug"><a href="#toc">&nbsp;TOC&nbsp;</a></td></tr></table>
-<a name="rfc.section.2.2"></a><h3>2.2.&nbsp;
-Encapsulation</h3>
-
-<p>SATP does not depend on the lower layer protocol. This section only gives an example of how packets could look like.
-      
-</p><br /><hr class="insert" />
-<a name="transport_udp"></a>
-
-<p>Examples of SATP used with different lower layer and payload protocols
-</p><div style='display: table; width: 0; margin-left: 3em; margin-right: auto'><pre>
-    +------+-----+-------------------------------+
-    |      |     |      +----------------+-----+ |
-    | IPv6 | UDP | SATP | Ethernet 802.3 | ... | |
-    |      |     |      +----------------+-----+ |
-    +------+-----+-------------------------------+
-
-Tunneling of Ethernet over UDP/IPv6
-
-    +------+-----+---------------------------+
-    |      |     |      +------+-----+-----+ |
-    | IPv4 | UDP | SATP | IPv6 | UDP | RTP | |
-    |      |     |      +------+-----+-----+ |
-    +------+-----+---------------------------+
-
-Tunneling of IPv6 over UDP/IPv4 with RTP payload
-
-    +------+-------------------------------+
-    |      |      +----------------+-----+ |
-    | IPv6 | SATP | Ethernet 802.3 | ... | |
-    |      |      +----------------+-----+ |
-    +------+-------------------------------+
-
-Tunneling of Ethernet over IPv6
-
-    +------+---------------------------+
-    |      |      +------+-----+-----+ |
-    | IPv4 | SATP | IPv6 | UDP | RTP | |
-    |      |      +------+-----+-----+ |
-    +------+---------------------------+
-
-Tunneling of IPv6 over IPv4 with RTP payload
-</pre></div><table border="0" cellpadding="0" cellspacing="2" align="center"><tr><td align="center"><font face="monaco, MS Sans Serif" size="1"><b>&nbsp;Figure&nbsp;4&nbsp;</b></font><br /></td></tr></table><hr class="insert" />
-
-<a name="anchor9"></a><br /><hr />
-<table summary="layout" cellpadding="0" cellspacing="2" class="TOCbug" align="right"><tr><td class="TOCbug"><a href="#toc">&nbsp;TOC&nbsp;</a></td></tr></table>
-<a name="rfc.section.3"></a><h3>3.&nbsp;
-Using SATP on top of IP</h3>
-
-<a name="anchor10"></a><br /><hr />
-<table summary="layout" cellpadding="0" cellspacing="2" class="TOCbug" align="right"><tr><td class="TOCbug"><a href="#toc">&nbsp;TOC&nbsp;</a></td></tr></table>
-<a name="rfc.section.3.1"></a><h3>3.1.&nbsp;
-Fragmentation</h3>
-
-<p>
-           The only way of fully supporting fragmentation would be to synchronise fragments between all anycast servers. This is considered to be too much overhead, so there are two non-perfect solutions for these problems. Either fragmentation HAS TO be disabled or if not all fragments arrive at the same server the IP datagramm HAS TO be discarded. As routing changes are not expected to occur very frequently, the encapsulated protocol can do a retransmission and all fragments will arrive at the new server. 
-         
-</p>
-<p>If the payload type is IP and the IP headers' Don't Fragment (DF) bit is set, then the DF bit of the outer IP header HAS TO be set as well.
-</p>
-<a name="anchor11"></a><br /><hr />
-<table summary="layout" cellpadding="0" cellspacing="2" class="TOCbug" align="right"><tr><td class="TOCbug"><a href="#toc">&nbsp;TOC&nbsp;</a></td></tr></table>
-<a name="rfc.section.3.2"></a><h3>3.2.&nbsp;
-ICMP messages</h3>
-
-<p>ICMP messages MUST be relayed according to <a class='info' href='#RFC2003'>rfc2003 section 4<span> (</span><span class='info'>Perkins, C., &ldquo;IP Encapsulation within IP,&rdquo; October&nbsp;1996.</span><span>)</span></a> [RFC2003]. This is needed for path MTU detection.
-</p>
-<a name="anchor12"></a><br /><hr />
-<table summary="layout" cellpadding="0" cellspacing="2" class="TOCbug" align="right"><tr><td class="TOCbug"><a href="#toc">&nbsp;TOC&nbsp;</a></td></tr></table>
-<a name="rfc.section.4"></a><h3>4.&nbsp;
-Protocol specification</h3>
-
-<a name="anchor13"></a><br /><hr />
-<table summary="layout" cellpadding="0" cellspacing="2" class="TOCbug" align="right"><tr><td class="TOCbug"><a href="#toc">&nbsp;TOC&nbsp;</a></td></tr></table>
-<a name="rfc.section.4.1"></a><h3>4.1.&nbsp;
-Header format</h3>
-<br /><hr class="insert" />
-<a name="prot_header_table"></a>
-
-<p>Protocol Format
-</p><div style='display: table; width: 0; margin-left: 3em; margin-right: auto'><pre>
-      0                   1                   2                   3
-      0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
-     +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
-     |                         sequence number                       | |
-     +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ |
-     |           sender ID           |              MUX              | |
-   +#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+ |
-   | |         payload type          |                               | |
-   | +-------------------------------+                               | |
-   | |              ....        payload        ...                   | |
-   | |                               +-------------------------------+ |
-   | |                               | padding (OPT) | pad count(OPT)| |
-   +#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+-+
-   | ~                          MKI (OPTIONAL)                       ~ |
-   | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ |
-   | :                 authentication tag (RECOMMENDED)              : |
-   | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ |
-   |                                                                   |
-   +- Encrypted Portion                       Authenticated Portion ---+
-</pre></div><table border="0" cellpadding="0" cellspacing="2" align="center"><tr><td align="center"><font face="monaco, MS Sans Serif" size="1"><b>&nbsp;Figure&nbsp;5&nbsp;</b></font><br /></td></tr></table><hr class="insert" />
-
-<p>
-</p>
-<a name="anchor14"></a><br /><hr />
-<table summary="layout" cellpadding="0" cellspacing="2" class="TOCbug" align="right"><tr><td class="TOCbug"><a href="#toc">&nbsp;TOC&nbsp;</a></td></tr></table>
-<a name="rfc.section.4.2"></a><h3>4.2.&nbsp;
-sequence number</h3>
-
-<p>The sequence number is a 32 bit unsigned integer in network byte order. It starts with a random value and is increased by 1 for every sent packet. After the maximum value it starts over from 0. This overrun causes the ROC to be increased.
-</p>
-<a name="anchor15"></a><br /><hr />
-<table summary="layout" cellpadding="0" cellspacing="2" class="TOCbug" align="right"><tr><td class="TOCbug"><a href="#toc">&nbsp;TOC&nbsp;</a></td></tr></table>
-<a name="rfc.section.4.3"></a><h3>4.3.&nbsp;
-sender ID</h3>
-
-<p>The sender ID is a 16 bit unsigned integer. It HAS TO be unique for every sender sharing the same anycast address.
-</p>
-<a name="anchor16"></a><br /><hr />
-<table summary="layout" cellpadding="0" cellspacing="2" class="TOCbug" align="right"><tr><td class="TOCbug"><a href="#toc">&nbsp;TOC&nbsp;</a></td></tr></table>
-<a name="rfc.section.4.4"></a><h3>4.4.&nbsp;
-MUX</h3>
-
-<p>The MUX (multiplex) field is a 16 bit unsigned integer. It is used to distinguish multiple tunnel connections.
-</p>
-<a name="anchor17"></a><br /><hr />
-<table summary="layout" cellpadding="0" cellspacing="2" class="TOCbug" align="right"><tr><td class="TOCbug"><a href="#toc">&nbsp;TOC&nbsp;</a></td></tr></table>
-<a name="rfc.section.4.5"></a><h3>4.5.&nbsp;
-payload type</h3>
-
-<p>The payload type field defines the payload protocol. ETHER TYPE protocol numbers are used. <a href='http://www.iana.org/assignments/ethernet-numbers'>See IANA assigned ethernet numbers</a> . The values 0000-05DC are reserverd and MUST NOT be used. 
-        <br /><hr class="insert" />
-<a name="prot_type_table"></a>
-
-<p>Some examples for protocol numbers
-</p><div style='display: table; width: 0; margin-left: 3em; margin-right: auto'><pre>
-HEX
-0000 Reserved
-.... Reserved
-05DC Reserved
-0800 Internet IP (IPv4)
-6558 transparent ethernet bridging
-86DD IPv6
-</pre></div><table border="0" cellpadding="0" cellspacing="2" align="center"><tr><td align="center"><font face="monaco, MS Sans Serif" size="1"><b>&nbsp;Figure&nbsp;6&nbsp;</b></font><br /></td></tr></table><hr class="insert" />
-
-
-
-<a name="anchor18"></a><br /><hr />
-<table summary="layout" cellpadding="0" cellspacing="2" class="TOCbug" align="right"><tr><td class="TOCbug"><a href="#toc">&nbsp;TOC&nbsp;</a></td></tr></table>
-<a name="rfc.section.4.6"></a><h3>4.6.&nbsp;
-payload</h3>
-
-<p>A packet of type payload type (e.g. an IP packet).
-</p>
-<a name="anchor19"></a><br /><hr />
-<table summary="layout" cellpadding="0" cellspacing="2" class="TOCbug" align="right"><tr><td class="TOCbug"><a href="#toc">&nbsp;TOC&nbsp;</a></td></tr></table>
-<a name="rfc.section.4.7"></a><h3>4.7.&nbsp;
-padding (OPTIONAL)</h3>
-
-<p>Padding of max 255 octets.
-None of the pre-defined encryption transforms uses any padding; for
-   these, the plaintext and encrypted payload sizes match exactly. Transforms are based on transforms of the SRTP protocol and therefore might use the RTP padding format, so a RTP-like padding is supported. If the padding count field is present, the padding count field MUST be set to the padding length.
-</p>
-<a name="anchor20"></a><br /><hr />
-<table summary="layout" cellpadding="0" cellspacing="2" class="TOCbug" align="right"><tr><td class="TOCbug"><a href="#toc">&nbsp;TOC&nbsp;</a></td></tr></table>
-<a name="rfc.section.4.8"></a><h3>4.8.&nbsp;
-padding count (OPTIONAL)</h3>
-
-<p>The number of octets of the padding field. This field is optional. Its presence is signaled by the key management and not by this protocol. If this field isn't present, the padding field MUST NOT be present as well.
-</p>
-<a name="anchor21"></a><br /><hr />
-<table summary="layout" cellpadding="0" cellspacing="2" class="TOCbug" align="right"><tr><td class="TOCbug"><a href="#toc">&nbsp;TOC&nbsp;</a></td></tr></table>
-<a name="rfc.section.4.9"></a><h3>4.9.&nbsp;
-MKI (OPTIONAL)</h3>
-
-<p>The MKI (Master Key Identifier) is OPTIONAL and of configurable length. See <a class='info' href='#RFC3711'>SRTP Section 3.1<span> (</span><span class='info'>Baugher, M., McGrew, D., Naslund, M., Carrara, E., and K. Norrman, &ldquo;The Secure Real-time Transport Protocol (SRTP),&rdquo; March&nbsp;2004.</span><span>)</span></a> [RFC3711] for details.
-</p>
-<a name="anchor22"></a><br /><hr />
-<table summary="layout" cellpadding="0" cellspacing="2" class="TOCbug" align="right"><tr><td class="TOCbug"><a href="#toc">&nbsp;TOC&nbsp;</a></td></tr></table>
-<a name="rfc.section.4.10"></a><h3>4.10.&nbsp;
-authentication tag (RECOMMENDED)</h3>
-
-<p>The authentication tag is RECOMMENDED and of configurable length. It contains a cryptographic checksum of the sender ID, sequence number and the encrypted portion, but not of the MKI. On transmitter side encryption HAS TO be done before calculating the authentication tag. A receiver HAS TO calculate the authentication tag before decrypting the encrypted portion.
-</p>
-<a name="anchor23"></a><br /><hr />
-<table summary="layout" cellpadding="0" cellspacing="2" class="TOCbug" align="right"><tr><td class="TOCbug"><a href="#toc">&nbsp;TOC&nbsp;</a></td></tr></table>
-<a name="rfc.section.4.11"></a><h3>4.11.&nbsp;
-Encryption</h3>
-
-<p>Encryption is done in the same way as for <a class='info' href='#RFC3711'>SRTP<span> (</span><span class='info'>Baugher, M., McGrew, D., Naslund, M., Carrara, E., and K. Norrman, &ldquo;The Secure Real-time Transport Protocol (SRTP),&rdquo; March&nbsp;2004.</span><span>)</span></a> [RFC3711]. This section will only discuss some small changes that HAVE TO be made. Please read  <a class='info' href='#RFC3711'>SRTP RFC3711 section 3-9<span> (</span><span class='info'>Baugher, M., McGrew, D., Naslund, M., Carrara, E., and K. Norrman, &ldquo;The Secure Real-time Transport Protocol (SRTP),&rdquo; March&nbsp;2004.</span><span>)</span></a> [RFC3711] for details. 
-</p>
-<p>The least significant bits of SSRC are replaced by the sender ID and the most significant bits are replaced by the MUX. For the SRTP SEQ the 16 least significant bits of the SATP sequence number are used and the 16 most significant bits of the sequence number replace the 16 least significant bits of the SRTP ROC.
-</p><br /><hr class="insert" />
-<a name="srtp_vs_satp"></a>
-
-<p>Difference between SRTP and SATP
-</p><div style='display: table; width: 0; margin-left: 3em; margin-right: auto'><pre>
-      0                   1                   2                   3
-      0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
-     +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
-     |                     SATP    sequence number                   |
-     +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
-                                     =
-     +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
-     |  SRTP ROC least significant   |           SRTP SEQ            |
-     +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
-
-
-      0                   1                   2                   3
-      0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
-     +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
-     |           SATP  MUX           |       SATP sender ID          |
-     +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
-                                     =
-     +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
-     |                           SRTP SSRC                           |
-     +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
-</pre></div><table border="0" cellpadding="0" cellspacing="2" align="center"><tr><td align="center"><font face="monaco, MS Sans Serif" size="1"><b>&nbsp;Figure&nbsp;7&nbsp;</b></font><br /></td></tr></table><hr class="insert" />
-
-<a name="anchor24"></a><br /><hr />
-<table summary="layout" cellpadding="0" cellspacing="2" class="TOCbug" align="right"><tr><td class="TOCbug"><a href="#toc">&nbsp;TOC&nbsp;</a></td></tr></table>
-<a name="rfc.section.5"></a><h3>5.&nbsp;
-Security Considerations</h3>
-
-<p>As SATP uses the same encryption techniques as <a class='info' href='#RFC3711'>SRTP<span> (</span><span class='info'>Baugher, M., McGrew, D., Naslund, M., Carrara, E., and K. Norrman, &ldquo;The Secure Real-time Transport Protocol (SRTP),&rdquo; March&nbsp;2004.</span><span>)</span></a> [RFC3711], it shares the same security issues. This section will only discuss some small changes. Please read  <a class='info' href='#RFC3711'>SRTP RFC3711 section 9<span> (</span><span class='info'>Baugher, M., McGrew, D., Naslund, M., Carrara, E., and K. Norrman, &ldquo;The Secure Real-time Transport Protocol (SRTP),&rdquo; March&nbsp;2004.</span><span>)</span></a> [RFC3711] for details.
-</p>
-<a name="anchor25"></a><br /><hr />
-<table summary="layout" cellpadding="0" cellspacing="2" class="TOCbug" align="right"><tr><td class="TOCbug"><a href="#toc">&nbsp;TOC&nbsp;</a></td></tr></table>
-<a name="rfc.section.5.1"></a><h3>5.1.&nbsp;
-Replay protection</h3>
-
-<p>Replay protection is done by a replay list. Every anycast receiver has its own replay list, which SHOULDN'T be syncronised because of massive overhead. This leads to an additional possible attack. An attacker is able to replay a captured packet once to every anycast receiver. This attack is considered be very unlikely because multiple attack hosts in different locations are needed to reach seperate anycast receivers and the number of replays is limited to count of receivers - 1. Such replays might also happen because of routing problems, so a payload protocol HAS TO be robust against a small number of duplicated packages. The window size and position HAS TO be syncronised between multiple anycast receivers to limit this attack.
-</p>
-<a name="anchor26"></a><br /><hr />
-<table summary="layout" cellpadding="0" cellspacing="2" class="TOCbug" align="right"><tr><td class="TOCbug"><a href="#toc">&nbsp;TOC&nbsp;</a></td></tr></table>
-<a name="rfc.section.6"></a><h3>6.&nbsp;
-IANA Considerations</h3>
-
-<p>The protocol is intended to be used on top of IP or on top of UDP (to be compatible with NAT routers), so UDP and IP protocol numbers have to be assiged by IANA.
-</p>
-<a name="rfc.references"></a><br /><hr />
-<table summary="layout" cellpadding="0" cellspacing="2" class="TOCbug" align="right"><tr><td class="TOCbug"><a href="#toc">&nbsp;TOC&nbsp;</a></td></tr></table>
-<a name="rfc.section.7"></a><h3>7.&nbsp;
-References</h3>
-
-<a name="rfc.references1"></a><br /><hr />
-<table summary="layout" cellpadding="0" cellspacing="2" class="TOCbug" align="right"><tr><td class="TOCbug"><a href="#toc">&nbsp;TOC&nbsp;</a></td></tr></table>
-<h3>7.1.&nbsp;Normative References</h3>
-<table width="99%" border="0">
-<tr><td class="author-text" valign="top"><a name="RFC3711">[RFC3711]</a></td>
-<td class="author-text">Baugher, M., McGrew, D., Naslund, M., Carrara, E., and K. Norrman, &ldquo;<a href="http://tools.ietf.org/html/rfc3711">The Secure Real-time Transport Protocol (SRTP)</a>,&rdquo; RFC&nbsp;3711, March&nbsp;2004 (<a href="ftp://ftp.isi.edu/in-notes/rfc3711.txt">TXT</a>).</td></tr>
-<tr><td class="author-text" valign="top"><a name="RFC2119">[RFC2119]</a></td>
-<td class="author-text"><a href="mailto:sob@harvard.edu">Bradner, S.</a>, &ldquo;<a href="http://tools.ietf.org/html/rfc2119">Key words for use in RFCs to Indicate Requirement Levels</a>,&rdquo; BCP&nbsp;14, RFC&nbsp;2119, March&nbsp;1997 (<a href="ftp://ftp.isi.edu/in-notes/rfc2119.txt">TXT</a>, <a href="http://xml.resource.org/public/rfc/html/rfc2119.html">HTML</a>, <a href="http://xml.resource.org/public/rfc/xml/rfc2119.xml">XML</a>).</td></tr>
-<tr><td class="author-text" valign="top"><a name="RFC2003">[RFC2003]</a></td>
-<td class="author-text"><a href="mailto:perk@watson.ibm.com">Perkins, C.</a>, &ldquo;<a href="http://tools.ietf.org/html/rfc2003">IP Encapsulation within IP</a>,&rdquo; RFC&nbsp;2003, October&nbsp;1996 (<a href="ftp://ftp.isi.edu/in-notes/rfc2003.txt">TXT</a>, <a href="http://xml.resource.org/public/rfc/html/rfc2003.html">HTML</a>, <a href="http://xml.resource.org/public/rfc/xml/rfc2003.xml">XML</a>).</td></tr>
-</table>
-
-<a name="rfc.references2"></a><br /><hr />
-<table summary="layout" cellpadding="0" cellspacing="2" class="TOCbug" align="right"><tr><td class="TOCbug"><a href="#toc">&nbsp;TOC&nbsp;</a></td></tr></table>
-<h3>7.2.&nbsp;Informational References</h3>
-<table width="99%" border="0">
-<tr><td class="author-text" valign="top"><a name="RFC2784">[RFC2784]</a></td>
-<td class="author-text"><a href="mailto:dino@procket.com">Farinacci, D.</a>, <a href="mailto:tony1@home.net">Li, T.</a>, <a href="mailto:stan_hanks@enron.net">Hanks, S.</a>, <a href="mailto:dmm@cisco.com">Meyer, D.</a>, and <a href="mailto:pst@juniper.net">P. Traina</a>, &ldquo;<a href="http://tools.ietf.org/html/rfc2784">Generic Routing Encapsulation (GRE)</a>,&rdquo; RFC&nbsp;2784, March&nbsp;2000 (<a href="ftp://ftp.isi.edu/in-notes/rfc2784.txt">TXT</a>).</td></tr>
-<tr><td class="author-text" valign="top"><a name="RFC2401">[RFC2401]</a></td>
-<td class="author-text"><a href="mailto:kent@bbn.com">Kent, S.</a> and <a href="mailto:rja@corp.home.net">R. Atkinson</a>, &ldquo;<a href="http://tools.ietf.org/html/rfc2401">Security Architecture for the Internet Protocol</a>,&rdquo; RFC&nbsp;2401, November&nbsp;1998 (<a href="ftp://ftp.isi.edu/in-notes/rfc2401.txt">TXT</a>, <a href="http://xml.resource.org/public/rfc/html/rfc2401.html">HTML</a>, <a href="http://xml.resource.org/public/rfc/xml/rfc2401.xml">XML</a>).</td></tr>
-<tr><td class="author-text" valign="top"><a name="RFC1546">[RFC1546]</a></td>
-<td class="author-text"><a href="mailto:craig@bbn.com">Partridge, C.</a>, <a href="mailto:tmendez@bbn.com">Mendez, T.</a>, and <a href="mailto:milliken@bbn.com">W. Milliken</a>, &ldquo;<a href="http://tools.ietf.org/html/rfc1546">Host Anycasting Service</a>,&rdquo; RFC&nbsp;1546, November&nbsp;1993 (<a href="ftp://ftp.isi.edu/in-notes/rfc1546.txt">TXT</a>).</td></tr>
-</table>
-
-<a name="rfc.authors"></a><br /><hr />
-<table summary="layout" cellpadding="0" cellspacing="2" class="TOCbug" align="right"><tr><td class="TOCbug"><a href="#toc">&nbsp;TOC&nbsp;</a></td></tr></table>
-<h3>Author's Address</h3>
-<table width="99%" border="0" cellpadding="0" cellspacing="0">
-<tr><td class="author-text">&nbsp;</td>
-<td class="author-text">Othmar Gsenger</td></tr>
-<tr><td class="author-text">&nbsp;</td>
-<td class="author-text">Puerstingerstr 32</td></tr>
-<tr><td class="author-text">&nbsp;</td>
-<td class="author-text">Saalfelden  5760</td></tr>
-<tr><td class="author-text">&nbsp;</td>
-<td class="author-text">AT</td></tr>
-<tr><td class="author" align="right">Phone:&nbsp;</td>
-<td class="author-text"></td></tr>
-<tr><td class="author" align="right">Email:&nbsp;</td>
-<td class="author-text"><a href="mailto:satp@gsenger.com">satp@gsenger.com</a></td></tr>
-<tr><td class="author" align="right">URI:&nbsp;</td>
-<td class="author-text"><a href="http://www.gsenger.com/satp/">http://www.gsenger.com/satp/</a></td></tr>
-</table>
-<a name="rfc.copyright"></a><br /><hr />
-<table summary="layout" cellpadding="0" cellspacing="2" class="TOCbug" align="right"><tr><td class="TOCbug"><a href="#toc">&nbsp;TOC&nbsp;</a></td></tr></table>
-<h3>Full Copyright Statement</h3>
-<p class='copyright'>
-Copyright &copy; The IETF Trust (2008).</p>
-<p class='copyright'>
-This document is subject to the rights,
-licenses and restrictions contained in BCP&nbsp;78,
-and except as set forth therein,
-the authors retain all their rights.</p>
-<p class='copyright'>
-This document and the information contained herein are provided
-on an &ldquo;AS IS&rdquo; basis and THE CONTRIBUTOR,
-THE ORGANIZATION HE/SHE REPRESENTS
-OR IS SPONSORED BY (IF ANY), THE INTERNET SOCIETY, THE IETF TRUST
-AND THE INTERNET ENGINEERING TASK FORCE DISCLAIM ALL WARRANTIES,
-EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO ANY WARRANTY THAT
-THE USE OF THE INFORMATION HEREIN WILL NOT INFRINGE ANY RIGHTS OR ANY
-IMPLIED WARRANTIES OF MERCHANTABILITY OR FITNESS FOR A PARTICULAR
-PURPOSE.</p>
-<h3>Intellectual Property</h3>
-<p class='copyright'>
-The IETF takes no position regarding the validity or scope of any
-Intellectual Property Rights or other rights that might be claimed
-to pertain to the implementation or use of the technology
-described in this document or the extent to which any license
-under such rights might or might not be available; nor does it
-represent that it has made any independent effort to identify any
-such rights.
-Information on the procedures with respect to
-rights in RFC documents can be found in BCP&nbsp;78 and BCP&nbsp;79.</p>
-<p class='copyright'>
-Copies of IPR disclosures made to the IETF Secretariat and any
-assurances of licenses to be made available,
-or the result of an attempt made to obtain a general license or
-permission for the use of such proprietary rights by implementers or
-users of this specification can be obtained from the IETF on-line IPR
-repository at <a href='http://www.ietf.org/ipr'>http://www.ietf.org/ipr</a>.</p>
-<p class='copyright'>
-The IETF invites any interested party to bring to its attention
-any copyrights,
-patents or patent applications,
-or other
-proprietary rights that may cover technology that may be required
-to implement this standard.
-Please address the information to the IETF at <a href='mailto:ietf-ipr@ietf.org'>ietf-ipr@ietf.org</a>.</p>
-</body></html>
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-Network Working Group                                         O. Gsenger
-Internet-Draft                                                  May 2008
-Expires: November 2, 2008
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-                secure anycast tunneling protocol (SATP)
-           draft-gsenger-secure-anycast-tunneling-protocol-02
-
-Status of this Memo
-
-   By submitting this Internet-Draft, each author represents that any
-   applicable patent or other IPR claims of which he or she is aware
-   have been or will be disclosed, and any of which he or she becomes
-   aware will be disclosed, in accordance with Section 6 of BCP 79.
-
-   Internet-Drafts are working documents of the Internet Engineering
-   Task Force (IETF), its areas, and its working groups.  Note that
-   other groups may also distribute working documents as Internet-
-   Drafts.
-
-   Internet-Drafts are draft documents valid for a maximum of six months
-   and may be updated, replaced, or obsoleted by other documents at any
-   time.  It is inappropriate to use Internet-Drafts as reference
-   material or to cite them other than as "work in progress."
-
-   The list of current Internet-Drafts can be accessed at
-   http://www.ietf.org/ietf/1id-abstracts.txt.
-
-   The list of Internet-Draft Shadow Directories can be accessed at
-   http://www.ietf.org/shadow.html.
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-   This Internet-Draft will expire on November 2, 2008.
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-Abstract
-
-   The secure anycast tunneling protocol (SATP) defines a protocol used
-   for communication between any combination of unicast and anycast
-   tunnel endpoints.  It allows tunneling of every ETHER TYPE protocol
-   (ethernet, ip ...).  SATP directly includes cryptography and message
-   authentication based on the methods used by the Secure Real-time
-   Transport Protocol(SRTP) [RFC3711].  It can be used as an encrypted
-   alternative to IP Encapsulation within IP [RFC2003] and Generic
-   Routing Encapsulation (GRE) [RFC2784].  Both anycast receivers and
-   senders are supported.
-
-
-Table of Contents
-
-   1.  Introduction . . . . . . . . . . . . . . . . . . . . . . . . .  3
-     1.1.  Notational Conventions . . . . . . . . . . . . . . . . . .  3
-   2.  Motivation and usage scenarios . . . . . . . . . . . . . . . .  4
-     2.1.  Usage scenarions . . . . . . . . . . . . . . . . . . . . .  4
-       2.1.1.  Tunneling from unicast hosts over anycast routers
-               to other unicast hosts . . . . . . . . . . . . . . . .  4
-       2.1.2.  Tunneling from unicast hosts to anycast networks . . .  5
-       2.1.3.  Redundant tunnel connection of 2 networks  . . . . . .  5
-     2.2.  Encapsulation  . . . . . . . . . . . . . . . . . . . . . .  6
-   3.  Using SATP on top of IP  . . . . . . . . . . . . . . . . . . .  8
-     3.1.  Fragmentation  . . . . . . . . . . . . . . . . . . . . . .  8
-     3.2.  ICMP messages  . . . . . . . . . . . . . . . . . . . . . .  8
-   4.  Protocol specification . . . . . . . . . . . . . . . . . . . .  9
-     4.1.  Header format  . . . . . . . . . . . . . . . . . . . . . .  9
-     4.2.  sequence number  . . . . . . . . . . . . . . . . . . . . .  9
-     4.3.  sender ID  . . . . . . . . . . . . . . . . . . . . . . . .  9
-     4.4.  MUX  . . . . . . . . . . . . . . . . . . . . . . . . . . .  9
-     4.5.  payload type . . . . . . . . . . . . . . . . . . . . . . . 10
-     4.6.  payload  . . . . . . . . . . . . . . . . . . . . . . . . . 10
-     4.7.  padding (OPTIONAL) . . . . . . . . . . . . . . . . . . . . 10
-     4.8.  padding count (OPTIONAL) . . . . . . . . . . . . . . . . . 10
-     4.9.  MKI (OPTIONAL) . . . . . . . . . . . . . . . . . . . . . . 10
-     4.10. authentication tag (RECOMMENDED) . . . . . . . . . . . . . 10
-     4.11. Encryption . . . . . . . . . . . . . . . . . . . . . . . . 11
-   5.  Security Considerations  . . . . . . . . . . . . . . . . . . . 12
-     5.1.  Replay protection  . . . . . . . . . . . . . . . . . . . . 12
-   6.  IANA Considerations  . . . . . . . . . . . . . . . . . . . . . 13
-   7.  References . . . . . . . . . . . . . . . . . . . . . . . . . . 14
-     7.1.  Normative References . . . . . . . . . . . . . . . . . . . 14
-     7.2.  Informational References . . . . . . . . . . . . . . . . . 14
-   Author's Address . . . . . . . . . . . . . . . . . . . . . . . . . 16
-   Intellectual Property and Copyright Statements . . . . . . . . . . 17
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-1.  Introduction
-
-   SATP is a mixture of a generic encapsulation protocol like GRE
-   [RFC2784] and a secure tunneling protocol as IPsec [RFC2401] in
-   tunnel mode.  It can be used to build redundant virtual private
-   network (VPN) connections.  It supports peer-to-peer tunnels, where
-   tunnel endpoints can be any combination of unicast, multicast or
-   anycast hosts, so it defines a Host Anycast Service [RFC1546].
-   Encryption is done per packet, so the protocol is robust against
-   packet loss and routing changes.  To reduce header overhead,
-   encryption techniques of SRTP [RFC3711] are being used.
-
-1.1.  Notational Conventions
-
-   The keywords "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT",
-   "SHOULD", "SHOULD NOT", "RECOMMENDED", "MAY", and "OPTIONAL" in this
-   document are to be interpreted as described in RFC2119 [RFC2119].
-
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-2.  Motivation and usage scenarios
-
-   This section gives an overview of possible usage scenarios.  Please
-   note that the protocols used in the figures are only examples and
-   that SATP itself does not care about either transport protocols or
-   encapsulated protocols.  Routing is not done by SATP and each
-   implemetation MAY choose it's own way of doing this task (e.g. using
-   functions provided by the operating system).  SATP is used only to
-   encapsulate and encrypt data.
-
-2.1.  Usage scenarions
-
-2.1.1.  Tunneling from unicast hosts over anycast routers to other
-        unicast hosts
-
-   An example of SATP used to tunnel in a unicast client - anycast
-   server model
-
-                       --------- router -----------
-                      /                            \
-       unicast ------+---------- router ------------+------ unicast
-       host           \                            /        host
-                       --------- router -----------
-
-     unicast  | encrypted     |  anycast  | encrypted     |  unicast
-     tunnel   | communication |  tunnel   | communication |  tunnel
-     endpoint | using SATP    |  endpoint | using SATP    |  endpoint
-
-                                 Figure 1
-
-   In this scenario the payload is encapsuleted into a SATP packet by a
-   unicast host and gets transmitted to one of the anycast routers.
-   After transmisson the packet gets decapsulated by the router.  This
-   router makes a routing descision based on the underlying protocol and
-   transmits a new SATP package to one or more unicast hosts depending
-   on this decision.
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-2.1.2.  Tunneling from unicast hosts to anycast networks
-
-   An example of SATP used to encrypt data between a unicast host and
-   anycast networks
-
-                          -------Router -+---- DNS Server
-                         /                \
-                        /                  --- 6to4 Router
-                       /
-       unicast -------+----------Router --+--- DNS Server
-       host            \                   \
-                        \                   --- 6to4 Router
-                         \
-                          -------Router -+---- DNS Server
-                                          \
-                                           --- 6to4 Router
-
-     unicast  | encrypted     |  anycast  | plaintext
-     tunnel   | communication |  tunnel   | anycast
-     endpoint | using SATP    |  endpoint | services
-
-
-                                 Figure 2
-
-   When the unicast hosts wants to transmit data to one of the anycast
-   DNS servers, it encapsulates the data and sends a SATP packet to the
-   anycast address of the routers.  The packet arrives at one of the
-   routers, gets decapsulated and is then forwarded to the DNS server.
-   This method can be used to tunnel between clients and networks
-   providing anycast services.  It can also be used the other way to
-   virtually locate a unicast service within anycasted networks.
-
-2.1.3.  Redundant tunnel connection of 2 networks
-
-   An example of SATP used to connect 2 networks
-
-                 Router -----------   ---------------Router
-               /                   \ /                     \
-       Network - Router ------------x                       Network
-          A    \                   / \                     /   B
-                 Router -----------   ---------------Router
-
-               | packets       |  packets  |  packets      |
-    plaintext  | get           |  take a   |  get          | plaintext
-    packets    | de/encrypted  |  random   |  de/encrypted | packets
-               |de/encapsulated|   path    |de/encapsulated|
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-                                 Figure 3
-
-   Network A has multiple routers which act as gateway/tunnel endpoints
-   to another network B. This way a redundant encrypted tunnel
-   connection between the two networks is built up.  All tunnel
-   endpoints of network A share the same anycast address and all tunnel
-   endpoints of network B share another anycast address.  When a packet
-   from network A is transmitted to network B, it first arrives on one
-   of network A's border routers.  Which router is used is determined by
-   network A's internal routing.  This router encapsulates the package
-   and sends it to the anycast address of network B's routers.  After
-   arrival the SATP packet gets decapsulated and routed to its
-   destination within network B.
-
-2.2.  Encapsulation
-
-   SATP does not depend on the lower layer protocol.  This section only
-   gives an example of how packets could look like.
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-   Examples of SATP used with different lower layer and payload
-   protocols
-
-       +------+-----+-------------------------------+
-       |      |     |      +----------------+-----+ |
-       | IPv6 | UDP | SATP | Ethernet 802.3 | ... | |
-       |      |     |      +----------------+-----+ |
-       +------+-----+-------------------------------+
-
-   Tunneling of Ethernet over UDP/IPv6
-
-       +------+-----+---------------------------+
-       |      |     |      +------+-----+-----+ |
-       | IPv4 | UDP | SATP | IPv6 | UDP | RTP | |
-       |      |     |      +------+-----+-----+ |
-       +------+-----+---------------------------+
-
-   Tunneling of IPv6 over UDP/IPv4 with RTP payload
-
-       +------+-------------------------------+
-       |      |      +----------------+-----+ |
-       | IPv6 | SATP | Ethernet 802.3 | ... | |
-       |      |      +----------------+-----+ |
-       +------+-------------------------------+
-
-   Tunneling of Ethernet over IPv6
-
-       +------+---------------------------+
-       |      |      +------+-----+-----+ |
-       | IPv4 | SATP | IPv6 | UDP | RTP | |
-       |      |      +------+-----+-----+ |
-       +------+---------------------------+
-
-   Tunneling of IPv6 over IPv4 with RTP payload
-
-                                 Figure 4
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-3.  Using SATP on top of IP
-
-3.1.  Fragmentation
-
-   The only way of fully supporting fragmentation would be to
-   synchronise fragments between all anycast servers.  This is
-   considered to be too much overhead, so there are two non-perfect
-   solutions for these problems.  Either fragmentation HAS TO be
-   disabled or if not all fragments arrive at the same server the IP
-   datagramm HAS TO be discarded.  As routing changes are not expected
-   to occur very frequently, the encapsulated protocol can do a
-   retransmission and all fragments will arrive at the new server.
-
-   If the payload type is IP and the IP headers' Don't Fragment (DF) bit
-   is set, then the DF bit of the outer IP header HAS TO be set as well.
-
-3.2.  ICMP messages
-
-   ICMP messages MUST be relayed according to rfc2003 section 4
-   [RFC2003].  This is needed for path MTU detection.
-
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-4.  Protocol specification
-
-4.1.  Header format
-
-   Protocol Format
-
-      0                   1                   2                   3
-      0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
-     +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
-     |                         sequence number                       | |
-     +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ |
-     |           sender ID           |              MUX              | |
-   +#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+ |
-   | |         payload type          |                               | |
-   | +-------------------------------+                               | |
-   | |              ....        payload        ...                   | |
-   | |                               +-------------------------------+ |
-   | |                               | padding (OPT) | pad count(OPT)| |
-   +#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+-+
-   | ~                          MKI (OPTIONAL)                       ~ |
-   | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ |
-   | :                 authentication tag (RECOMMENDED)              : |
-   | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ |
-   |                                                                   |
-   +- Encrypted Portion                       Authenticated Portion ---+
-
-                                 Figure 5
-
-4.2.  sequence number
-
-   The sequence number is a 32 bit unsigned integer in network byte
-   order.  It starts with a random value and is increased by 1 for every
-   sent packet.  After the maximum value it starts over from 0.  This
-   overrun causes the ROC to be increased.
-
-4.3.  sender ID
-
-   The sender ID is a 16 bit unsigned integer.  It HAS TO be unique for
-   every sender sharing the same anycast address.
-
-4.4.  MUX
-
-   The MUX (multiplex) field is a 16 bit unsigned integer.  It is used
-   to distinguish multiple tunnel connections.
-
-
-
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-
-
-4.5.  payload type
-
-   The payload type field defines the payload protocol.  ETHER TYPE
-   protocol numbers are used.  See IANA assigned ethernet numbers [1] .
-   The values 0000-05DC are reserverd and MUST NOT be used.
-
-   Some examples for protocol numbers
-
-   HEX
-   0000 Reserved
-   .... Reserved
-   05DC Reserved
-   0800 Internet IP (IPv4)
-   6558 transparent ethernet bridging
-   86DD IPv6
-
-                                 Figure 6
-
-4.6.  payload
-
-   A packet of type payload type (e.g. an IP packet).
-
-4.7.  padding (OPTIONAL)
-
-   Padding of max 255 octets.  None of the pre-defined encryption
-   transforms uses any padding; for these, the plaintext and encrypted
-   payload sizes match exactly.  Transforms are based on transforms of
-   the SRTP protocol and therefore might use the RTP padding format, so
-   a RTP-like padding is supported.  If the padding count field is
-   present, the padding count field MUST be set to the padding length.
-
-4.8.  padding count (OPTIONAL)
-
-   The number of octets of the padding field.  This field is optional.
-   Its presence is signaled by the key management and not by this
-   protocol.  If this field isn't present, the padding field MUST NOT be
-   present as well.
-
-4.9.  MKI (OPTIONAL)
-
-   The MKI (Master Key Identifier) is OPTIONAL and of configurable
-   length.  See SRTP Section 3.1 [RFC3711] for details.
-
-4.10.  authentication tag (RECOMMENDED)
-
-   The authentication tag is RECOMMENDED and of configurable length.  It
-   contains a cryptographic checksum of the sender ID, sequence number
-   and the encrypted portion, but not of the MKI.  On transmitter side
-
-
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-
-
-   encryption HAS TO be done before calculating the authentication tag.
-   A receiver HAS TO calculate the authentication tag before decrypting
-   the encrypted portion.
-
-4.11.  Encryption
-
-   Encryption is done in the same way as for SRTP [RFC3711].  This
-   section will only discuss some small changes that HAVE TO be made.
-   Please read SRTP RFC3711 section 3-9 [RFC3711] for details.
-
-   The least significant bits of SSRC are replaced by the sender ID and
-   the most significant bits are replaced by the MUX.  For the SRTP SEQ
-   the 16 least significant bits of the SATP sequence number are used
-   and the 16 most significant bits of the sequence number replace the
-   16 least significant bits of the SRTP ROC.
-
-   Difference between SRTP and SATP
-
-        0                   1                   2                   3
-        0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
-       +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
-       |                     SATP    sequence number                   |
-       +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
-                                       =
-       +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
-       |  SRTP ROC least significant   |           SRTP SEQ            |
-       +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
-
-
-        0                   1                   2                   3
-        0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
-       +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
-       |           SATP  MUX           |       SATP sender ID          |
-       +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
-                                       =
-       +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
-       |                           SRTP SSRC                           |
-       +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
-
-                                 Figure 7
-
-
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-
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-
-
-5.  Security Considerations
-
-   As SATP uses the same encryption techniques as SRTP [RFC3711], it
-   shares the same security issues.  This section will only discuss some
-   small changes.  Please read SRTP RFC3711 section 9 [RFC3711] for
-   details.
-
-5.1.  Replay protection
-
-   Replay protection is done by a replay list.  Every anycast receiver
-   has its own replay list, which SHOULDN'T be syncronised because of
-   massive overhead.  This leads to an additional possible attack.  An
-   attacker is able to replay a captured packet once to every anycast
-   receiver.  This attack is considered be very unlikely because
-   multiple attack hosts in different locations are needed to reach
-   seperate anycast receivers and the number of replays is limited to
-   count of receivers - 1.  Such replays might also happen because of
-   routing problems, so a payload protocol HAS TO be robust against a
-   small number of duplicated packages.  The window size and position
-   HAS TO be syncronised between multiple anycast receivers to limit
-   this attack.
-
-
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-
-
-6.  IANA Considerations
-
-   The protocol is intended to be used on top of IP or on top of UDP (to
-   be compatible with NAT routers), so UDP and IP protocol numbers have
-   to be assiged by IANA.
-
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-
-7.  References
-
-7.1.  Normative References
-
-   [RFC3711]  Baugher, M., McGrew, D., Naslund, M., Carrara, E., and K.
-              Norrman, "The Secure Real-time Transport Protocol (SRTP)",
-              RFC 3711, March 2004.
-
-   [RFC2119]  Bradner, S., "Key words for use in RFCs to Indicate
-              Requirement Levels", BCP 14, RFC 2119, March 1997.
-
-   [RFC2003]  Perkins, C., "IP Encapsulation within IP", RFC 2003,
-              October 1996.
-
-7.2.  Informational References
-
-   [RFC2784]  Farinacci, D., Li, T., Hanks, S., Meyer, D., and P.
-              Traina, "Generic Routing Encapsulation (GRE)", RFC 2784,
-              March 2000.
-
-   [RFC2401]  Kent, S. and R. Atkinson, "Security Architecture for the
-              Internet Protocol", RFC 2401, November 1998.
-
-   [RFC1546]  Partridge, C., Mendez, T., and W. Milliken, "Host
-              Anycasting Service", RFC 1546, November 1993.
-
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-   [1]  <http://www.iana.org/assignments/ethernet-numbers>
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-Author's Address
-
-   Othmar Gsenger
-   Puerstingerstr 32
-   Saalfelden  5760
-   AT
-
-   Phone:
-   Email: satp@gsenger.com
-   URI:   http://www.gsenger.com/satp/
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-
-Full Copyright Statement
-
-   Copyright (C) The IETF Trust (2008).
-
-   This document is subject to the rights, licenses and restrictions
-   contained in BCP 78, and except as set forth therein, the authors
-   retain all their rights.
-
-   This document and the information contained herein are provided on an
-   "AS IS" basis and THE CONTRIBUTOR, THE ORGANIZATION HE/SHE REPRESENTS
-   OR IS SPONSORED BY (IF ANY), THE INTERNET SOCIETY, THE IETF TRUST AND
-   THE INTERNET ENGINEERING TASK FORCE DISCLAIM ALL WARRANTIES, EXPRESS
-   OR IMPLIED, INCLUDING BUT NOT LIMITED TO ANY WARRANTY THAT THE USE OF
-   THE INFORMATION HEREIN WILL NOT INFRINGE ANY RIGHTS OR ANY IMPLIED
-   WARRANTIES OF MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE.
-
-
-Intellectual Property
-
-   The IETF takes no position regarding the validity or scope of any
-   Intellectual Property Rights or other rights that might be claimed to
-   pertain to the implementation or use of the technology described in
-   this document or the extent to which any license under such rights
-   might or might not be available; nor does it represent that it has
-   made any independent effort to identify any such rights.  Information
-   on the procedures with respect to rights in RFC documents can be
-   found in BCP 78 and BCP 79.
-
-   Copies of IPR disclosures made to the IETF Secretariat and any
-   assurances of licenses to be made available, or the result of an
-   attempt made to obtain a general license or permission for the use of
-   such proprietary rights by implementers or users of this
-   specification can be obtained from the IETF on-line IPR repository at
-   http://www.ietf.org/ipr.
-
-   The IETF invites any interested party to bring to its attention any
-   copyrights, patents or patent applications, or other proprietary
-   rights that may cover technology that may be required to implement
-   this standard.  Please address the information to the IETF at
-   ietf-ipr@ietf.org.
-
-
-
-
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-
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diff --git a/papers/draft-gsenger-secure-anycast-tunneling-protocol-02.xml b/papers/draft-gsenger-secure-anycast-tunneling-protocol-02.xml
deleted file mode 100644
index 78f3414..0000000
--- a/papers/draft-gsenger-secure-anycast-tunneling-protocol-02.xml
+++ /dev/null
@@ -1,299 +0,0 @@
-<?xml version='1.0'?>
-    <!DOCTYPE rfc SYSTEM 'rfcXXXX.dtd' [
-    
-    <!ENTITY rfc1546 PUBLIC '' 'http://xml.resource.org/public/rfc/bibxml/reference.RFC.1546.xml'>
-    <!ENTITY rfc3711 PUBLIC '' 'http://xml.resource.org/public/rfc/bibxml/reference.RFC.3711.xml'>
-    <!ENTITY rfc3068 PUBLIC '' 'http://xml.resource.org/public/rfc/bibxml/reference.RFC.3068.xml'>
-    <!ENTITY rfc2784 PUBLIC '' 'http://xml.resource.org/public/rfc/bibxml/reference.RFC.2784.xml'>
-    <!ENTITY rfc2401 PUBLIC '' 'http://xml.resource.org/public/rfc/bibxml/reference.RFC.2401.xml'>
-    <!ENTITY rfc2119 PUBLIC '' 'http://xml.resource.org/public/rfc/bibxml/reference.RFC.2119.xml'>
-    <!ENTITY rfc2003 PUBLIC '' 'http://xml.resource.org/public/rfc/bibxml/reference.RFC.2003.xml'>
-]>
-<?rfc toc='yes'?>
-    <rfc ipr='full3978' docName='draft-gsenger-secure-anycast-tunneling-protocol-02'>
-    <front>
-        <title>secure anycast tunneling protocol (SATP)</title>
-
-        <author initials='O.G.' surname='Gsenger'
-                fullname='Othmar Gsenger'>
-            <organization></organization>
-
-            <address>
-                <postal>
-                    <street>Puerstingerstr 32</street>
-                    <city>Saalfelden</city>
-                    <code>5760</code>
-                    <country>AT</country>
-                </postal>
-
-                <phone></phone>
-                <email>satp@gsenger.com</email>
-                <uri>http://www.gsenger.com/satp/</uri>
-            </address>
-        </author>
-
-        <date month='May' year='2008' />
-
-        <area>General</area>
-        <workgroup></workgroup>
-        <keyword>satp</keyword>
-        <keyword>Internet-Draft</keyword>
-        <keyword>secure anycast tunneling protocol</keyword>
-        <keyword>anycast</keyword>
-        <keyword>tunnel</keyword>
-        <keyword>secure</keyword>
-        <keyword>protocol</keyword>
-        <abstract>
-            <t>The secure anycast tunneling protocol (SATP) defines a protocol used for communication between any combination of unicast and anycast tunnel endpoints. It allows tunneling of every ETHER TYPE protocol (ethernet, ip ...). SATP directly includes cryptography and message authentication based on the methods used by the <xref target="RFC3711">Secure Real-time Transport Protocol(SRTP)</xref>. It can be used as an encrypted alternative to <xref target="RFC2003">IP Encapsulation within IP</xref> and <xref target="RFC2784">Generic Routing Encapsulation (GRE)</xref>. Both anycast receivers and senders are supported.
-            </t>
-        </abstract>
-    </front>
-    <middle>
-    <section title='Introduction'>
-        <t>SATP is a mixture of a generic encapsulation protocol like <xref target="RFC2784">GRE</xref> and a secure tunneling protocol as <xref target="RFC2401">IPsec</xref> in tunnel mode.  It can be used to build redundant virtual private network (VPN) connections.  It supports peer-to-peer tunnels, where tunnel endpoints can be any combination of unicast, multicast or anycast hosts, so it defines a <xref target="RFC1546">Host Anycast Service</xref>. Encryption is done per packet, so the protocol is robust against packet loss and routing changes.
-				To reduce header overhead, encryption techniques of <xref target="RFC3711">SRTP</xref> are being used. 
-				</t>
-      <section title='Notational Conventions'>
-        <t>The keywords "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT", "SHOULD", "SHOULD NOT", "RECOMMENDED", "MAY", and "OPTIONAL" in this document are to be interpreted as described in  <xref target="RFC2119">RFC2119</xref>.</t>
-       </section>
-    </section> 
-    <section title="Motivation and usage scenarios">
-       <t>This section gives an overview of possible usage scenarios. Please note that the protocols used in the figures are only examples and that SATP itself does not care about either transport protocols or encapsulated protocols. Routing is not done by SATP and each implemetation MAY choose it's own way of doing this task (e.g. using functions provided by the operating system). SATP is used only to encapsulate and encrypt data.</t>
-       <section title="Usage scenarions">
-    
-            <section title='Tunneling from unicast hosts over anycast routers to other unicast hosts'>
-              <figure anchor="tunnel_mode">
-                 <preamble>An example of SATP used to tunnel in a unicast client - anycast server model</preamble>
-                 <artwork>
-                    --------- router ----------- 
-                   /                            \ 
-    unicast ------+---------- router ------------+------ unicast
-    host           \                            /        host
-                    --------- router -----------  
-
-  unicast  | encrypted     |  anycast  | encrypted     |  unicast
-  tunnel   | communication |  tunnel   | communication |  tunnel  
-  endpoint | using SATP    |  endpoint | using SATP    |  endpoint 
-                 </artwork>
-       </figure>
-	      <t>In this scenario the payload is encapsuleted into a SATP packet by a unicast host and gets transmitted to one of the anycast routers. After transmisson the packet gets decapsulated by the router. This router makes a routing descision based on the underlying protocol and transmits a new SATP package to one or more unicast hosts depending on this decision.</t> 
-	    </section>
-
-	    <section title='Tunneling from unicast hosts to anycast networks'>
-              <figure anchor="open_tunnel_mode">
-                 <preamble>An example of SATP used to encrypt data between a unicast host and anycast networks</preamble>
-                 <artwork>
-                       -------Router -+---- DNS Server
-                      /                \ 
-                     /                  --- 6to4 Router
-                    /
-    unicast -------+----------Router --+--- DNS Server
-    host            \                   \  
-                     \                   --- 6to4 Router
-                      \
-                       -------Router -+---- DNS Server
-                                       \
-                                        --- 6to4 Router
-
-  unicast  | encrypted     |  anycast  | plaintext
-  tunnel   | communication |  tunnel   | anycast
-  endpoint | using SATP    |  endpoint | services
-
-                 </artwork>
-               </figure>
-            <t>When the unicast hosts wants to transmit data to one of the anycast DNS servers, it encapsulates the data and sends a SATP packet to the anycast address of the routers. The packet arrives at one of the routers, gets decapsulated and is then forwarded to the DNS server. This method can be used to tunnel between clients and networks providing anycast services. It can also be used the other way to virtually locate a unicast service within anycasted networks.</t>
-	    </section>
-      <section title='Redundant tunnel connection of 2 networks'>
-              <figure anchor="connect_networks">
-                 <preamble>An example of SATP used to connect 2 networks</preamble>
-                 <artwork>
-              Router -----------   ---------------Router
-            /                   \ /                     \
-    Network - Router ------------x                       Network
-       A    \                   / \                     /   B
-              Router -----------   ---------------Router
-
-            | packets       |  packets  |  packets      |
- plaintext  | get           |  take a   |  get          | plaintext
- packets    | de/encrypted  |  random   |  de/encrypted | packets
-            |de/encapsulated|   path    |de/encapsulated|              
-
-                 </artwork>
-       </figure>
-
-               <t>Network A has multiple routers which act as gateway/tunnel endpoints to another network B. This way a redundant encrypted tunnel connection between the two networks is built up. All tunnel endpoints of network A share the same anycast address and all tunnel endpoints of network B share another anycast address. When a packet from network A is transmitted to network B, it first arrives on one of network A's border routers. Which router is used is determined by network A's internal routing. This router encapsulates the package and sends it to the anycast address of network B's routers. After arrival the SATP packet gets decapsulated and routed to its destination within network B.</t>
-      </section>
-    </section>
-	<section title="Encapsulation">
-      <t>SATP does not depend on the lower layer protocol. This section only gives an example of how packets could look like.
-      </t>
-      <figure anchor="transport_udp">
-        <preamble>Examples of SATP used with different lower layer and payload protocols</preamble>
-          <artwork>
-    +------+-----+-------------------------------+
-    |      |     |      +----------------+-----+ |
-    | IPv6 | UDP | SATP | Ethernet 802.3 | ... | |
-    |      |     |      +----------------+-----+ |
-    +------+-----+-------------------------------+
-
-Tunneling of Ethernet over UDP/IPv6
-
-    +------+-----+---------------------------+
-    |      |     |      +------+-----+-----+ |
-    | IPv4 | UDP | SATP | IPv6 | UDP | RTP | |
-    |      |     |      +------+-----+-----+ |
-    +------+-----+---------------------------+
-
-Tunneling of IPv6 over UDP/IPv4 with RTP payload
-
-    +------+-------------------------------+
-    |      |      +----------------+-----+ |
-    | IPv6 | SATP | Ethernet 802.3 | ... | |
-    |      |      +----------------+-----+ |
-    +------+-------------------------------+
-
-Tunneling of Ethernet over IPv6
-
-    +------+---------------------------+
-    |      |      +------+-----+-----+ |
-    | IPv4 | SATP | IPv6 | UDP | RTP | |
-    |      |      +------+-----+-----+ |
-    +------+---------------------------+
-
-Tunneling of IPv6 over IPv4 with RTP payload
-                 </artwork>
-       </figure>
-	  </section>
-	</section>
-  <section title="Using SATP on top of IP">
-         <section title="Fragmentation">
-         <t>
-           The only way of fully supporting fragmentation would be to synchronise fragments between all anycast servers. This is considered to be too much overhead, so there are two non-perfect solutions for these problems. Either fragmentation HAS TO be disabled or if not all fragments arrive at the same server the IP datagramm HAS TO be discarded. As routing changes are not expected to occur very frequently, the encapsulated protocol can do a retransmission and all fragments will arrive at the new server. 
-         </t><t>If the payload type is IP and the IP headers' Don't Fragment (DF) bit is set, then the DF bit of the outer IP header HAS TO be set as well.</t>
-         </section>
-	 <section title="ICMP messages">
-	   <t>ICMP messages MUST be relayed according to <xref target="RFC2003">rfc2003 section 4</xref>. This is needed for path MTU detection.</t>
-	 </section>
-     </section>
-     <section title="Protocol specification">
-       <section title="Header format">
-            <figure anchor="prot_header_table">
-               <preamble>Protocol Format</preamble>
-                 <artwork>
-      0                   1                   2                   3
-      0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
-     +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
-     |                         sequence number                       | |
-     +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ |
-     |           sender ID           |              MUX              | |
-   +#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+ |
-   | |         payload type          |                               | |
-   | +-------------------------------+                               | |
-   | |              ....        payload        ...                   | |
-   | |                               +-------------------------------+ |
-   | |                               | padding (OPT) | pad count(OPT)| |
-   +#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+#+-+
-   | ~                          MKI (OPTIONAL)                       ~ |
-   | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ |
-   | :                 authentication tag (RECOMMENDED)              : |
-   | +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+ |
-   |                                                                   |
-   +- Encrypted Portion                       Authenticated Portion ---+
-</artwork>
-</figure>
-<t></t>
-       </section>
-       <section title="sequence number">
-       <t>The sequence number is a 32 bit unsigned integer in network byte order. It starts with a random value and is increased by 1 for every sent packet. After the maximum value it starts over from 0. This overrun causes the ROC to be increased.</t>
-       </section>
-       <section title="sender ID">
-       <t>The sender ID is a 16 bit unsigned integer. It HAS TO be unique for every sender sharing the same anycast address.</t>
-       </section>
-       <section title="MUX">
-       <t>The MUX (multiplex) field is a 16 bit unsigned integer. It is used to distinguish multiple tunnel connections.</t>
-       </section>
-       <section title="payload type">
-         <t>The payload type field defines the payload protocol. ETHER TYPE protocol numbers are used. <eref target="http://www.iana.org/assignments/ethernet-numbers">See IANA assigned ethernet numbers</eref> . The values 0000-05DC are reserverd and MUST NOT be used. 
-        <figure anchor="prot_type_table">
-               <preamble>Some examples for protocol numbers</preamble>
-                 <artwork>
-HEX
-0000 Reserved
-.... Reserved
-05DC Reserved
-0800 Internet IP (IPv4)
-6558 transparent ethernet bridging
-86DD IPv6
-</artwork>
-</figure>
-</t>
-	     </section>
-       <section title="payload">
-       <t>A packet of type payload type (e.g. an IP packet).</t>
-       </section>
-       <section title="padding (OPTIONAL)">
-       <t>Padding of max 255 octets.
-None of the pre-defined encryption transforms uses any padding; for
-   these, the plaintext and encrypted payload sizes match exactly. Transforms are based on transforms of the SRTP protocol and therefore might use the RTP padding format, so a RTP-like padding is supported. If the padding count field is present, the padding count field MUST be set to the padding length.</t>
-       </section>
-       <section title="padding count (OPTIONAL)">
-       <t>The number of octets of the padding field. This field is optional. Its presence is signaled by the key management and not by this protocol. If this field isn't present, the padding field MUST NOT be present as well.</t>
-       </section>
-        <section title="MKI (OPTIONAL)">
-        <t>The MKI (Master Key Identifier) is OPTIONAL and of configurable length. See <xref target="RFC3711">SRTP Section 3.1</xref> for details.</t>
-        </section>
-	<section title="authentication tag (RECOMMENDED)">
-	<t>The authentication tag is RECOMMENDED and of configurable length. It contains a cryptographic checksum of the sender ID, sequence number and the encrypted portion, but not of the MKI. On transmitter side encryption HAS TO be done before calculating the authentication tag. A receiver HAS TO calculate the authentication tag before decrypting the encrypted portion.</t>
-	</section>
-    <section title="Encryption">
-     <t>Encryption is done in the same way as for <xref target="RFC3711">SRTP</xref>. This section will only discuss some small changes that HAVE TO be made. Please read  <xref target="RFC3711">SRTP RFC3711 section 3-9</xref> for details. </t><t>The least significant bits of SSRC are replaced by the sender ID and the most significant bits are replaced by the MUX. For the SRTP SEQ the 16 least significant bits of the SATP sequence number are used and the 16 most significant bits of the sequence number replace the 16 least significant bits of the SRTP ROC.</t>
-   <figure anchor="srtp_vs_satp">
-      <preamble>Difference between SRTP and SATP</preamble>
-      <artwork>
-      0                   1                   2                   3
-      0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
-     +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
-     |                     SATP    sequence number                   |
-     +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
-                                     =
-     +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
-     |  SRTP ROC least significant   |           SRTP SEQ            |
-     +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
-
-
-      0                   1                   2                   3
-      0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
-     +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
-     |           SATP  MUX           |       SATP sender ID          |
-     +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
-                                     =
-     +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
-     |                           SRTP SSRC                           |
-     +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
-      </artwork>
-    </figure>
-    </section>
-  </section>
-    <section title="Security Considerations">
-     <t>As SATP uses the same encryption techniques as <xref target="RFC3711">SRTP</xref>, it shares the same security issues. This section will only discuss some small changes. Please read  <xref target="RFC3711">SRTP RFC3711 section 9</xref> for details.</t>
-      <section title="Replay protection">
-      <t>Replay protection is done by a replay list. Every anycast receiver has its own replay list, which SHOULDN'T be syncronised because of massive overhead. This leads to an additional possible attack. An attacker is able to replay a captured packet once to every anycast receiver. This attack is considered be very unlikely because multiple attack hosts in different locations are needed to reach seperate anycast receivers and the number of replays is limited to count of receivers - 1. Such replays might also happen because of routing problems, so a payload protocol HAS TO be robust against a small number of duplicated packages. The window size and position HAS TO be syncronised between multiple anycast receivers to limit this attack.</t>
-      </section>
-    </section>
-    <section title="IANA Considerations">
-      <t>The protocol is intended to be used on top of IP or on top of UDP (to be compatible with NAT routers), so UDP and IP protocol numbers have to be assiged by IANA.</t>
-    </section>
-    </middle>
-    <back>
-      <references title="Normative References">
-        &rfc3711;
-        &rfc2119;
-	&rfc2003;
-      </references>
-      <references title="Informational References">
-        &rfc2784; 
-        &rfc2401;
-        &rfc1546;
-      </references>
-    </back>
-    </rfc>
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@@ -1,21 +0,0 @@
-
-Title: Anycast services and routing
-
-Subtitle: How to build highly redundant and scaleable internet services with anycast
-
-Abstract:
-
-The talk will give an overview on internet routing and anycast ip addressing. We'll show how anycast can be used to build scaleable and redundant network services and to protect against deny of service attacks.
-
-description:
-
-Anycast like unicast or multicast is a special form of addressing on the internet. Two or more hosts share the same IP address, but only one of them gets the IP packets. Wich host recieves packages is usally determined by the routing protocol, so this might theoretically change after every packet.
-
-This adds many nice features, as it is possible to hot add and remove anycast hosts without reconfiguring any client using their services. When one anycast host fails, all it's traffic gets rerouted within seconds. So usally clients don't even recognise a server failure. Load balancing between the anycast hosts is automatically done by the routing protocol. So load balancing is based on best routing metric, which means the host with shortest path to the client is used. This leads to an optimal load balancing that serves all clients with minimum delay.
-
-Not every protocol can be used with anycast. Today mainly stateless protocols are used as anycast host services. However it is also possible to run more complex protocols between anycast and unicast hosts. The talk will discuss the design issues when building anycast host services. The secure anycast tunneling protocol (satp), will be presented as an example for a new anycast protocol. It allows to send encrypted data between any combination of unicast and anycast hosts. This may be used to build redundandt VPN clusters, but is also possible to use the protocol to build new services. On basis of a VOIP media relay a complex anycast design will be presented.
-
-On the internet a client cannot determine the difference between a normal multihomed IP address or an anycast IP address. Routing is done by BGP4. BGP bla.... Fine tuning, load banancing, failover whatever
-
-
-
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